KR20120016777A - Molding apparatus and method of hot stamping for controling partial strength - Google Patents

Abstract

PURPOSE: A hot stamping molding apparatus and method for partial strength control are provided to improve the exterior quality of a molded product by partially heating and cooling upper and lower molds. CONSTITUTION: A hot stamping molding apparatus comprises an upper mold(100), a lower mold(200), a sensing unit, and a temperature controller. The upper mold comprises an upper low-temperature mold(110), an upper high-temperature mold(120), and an upper insulating member which is arranged between the upper low- and high-temperature molds for shielding heat. The lower mold comprises a lower low-temperature mold(210), a lower high-temperature mold(220), and a lower insulating member which is arranged between the lower low- and high-temperature molds for shielding heat. The sensing unit detects the temperatures of the upper and lower high-temperature molds. The temperature controller controls the temperatures of the upper and lower high-temperature molds in order to correct the temperatures measured by the sensing unit to a target temperature.

Description

Hot stamping forming apparatus for local strength control and molding method {MOLDING APPARATUS AND METHOD OF HOT STAMPING FOR CONTROLING PARTIAL STRENGTH}

The present invention relates to a hot stamping forming apparatus for improving the collision energy absorption rate of high-strength body parts, and more particularly, local strength control to implement a high-strength region and a ductile region in the steel sheet through temperature control through local heating and cooling The present invention relates to a hot stamping molding apparatus and a molding method thereof.

In general, the hot stamping method forms a mold after cutting the raw material (iron plate) at a high temperature, and at the same time, gives a cooling effect to the mold, thereby rapidly reducing the temperature of the raw material. It is a way to improve the strength of the raw material to two to three times or more than the original.

As shown in FIG. 6, in the conventional hot stamping technique, the blank B before being cured from the wound bronze steel coil C is heated through the heating furnace O, and then presses through the robot R. It is conveyed to (P) side and press-molded.

Here, the press adopts the upper and lower molds of the press hardening mold, and the cooling water is supplied to the cooling water supply parts of the upper and lower molds to cure the surface structure of the blanks to cool the blanks.

This hot stamping technology heats the bronze iron plate at a high temperature during processing, so that the properties of the bronze iron plate are very soft and the stretching property is excellent, resulting in excellent moldability. Therefore, by using hot stamping, it is possible to manufacture desired parts with excellent formability while securing ultra high strength of the bronze iron sheet.

However, in the case of parts manufactured through hot stamping technology, since high strength is maintained throughout the parts, deformation for energy absorption is not easily performed during a vehicle crash. Therefore, when a vehicle crash occurs, passengers The problem is that a large injury is caused from an external shock.

On the other hand, in order to absorb the collision energy due to the vehicle crash, by adding a high-strength material rain force to the members of the low-strength material, it may be considered to partially strengthen the strength, in which case the manufacturing cost is increased and the vehicle The weight is increased to lower fuel economy.

Therefore, there is a demand for a method of increasing energy absorption rate of collision energy due to vehicle collision by inducing deformation in parts during vehicle collision.

SUMMARY OF THE INVENTION An object of the present invention for solving this problem is to provide a hot stamping forming apparatus and a forming method for local strength control to form a soft region and a high strength region in the heat treatment target to improve the absorption rate of collision energy and to realize a light weight. will be.

In order to achieve the above object, the hot stamping molding apparatus according to the present invention includes an upper mold, a lower mold, a sensing unit, and a temperature controller, wherein the upper mold is an upper high temperature mold and an upper high temperature mold and train assembled to the upper low temperature mold. An upper blocking member disposed between the upper low temperature mold and the upper high temperature mold, wherein the lower mold includes a lower high temperature mold and a lower high temperature mold assembled to the lower low temperature mold and the lower low temperature mold; A lower blocking member disposed between the high temperature molds, and a sensing unit detects temperatures of the upper high temperature molds and the lower high temperature molds, and a temperature controller is configured to compensate the measured temperature detected by the sensing unit with a target temperature. And adjust the temperature of the lower hot mold.

At this time, the upper low temperature mold and the lower low-temperature mold is provided with a cooling channel for maintaining the mold 20 ~ 80 ℃, the inside of the upper high temperature mold and the lower high temperature mold for maintaining the mold at 300 ~ 500 ℃ It is preferable that a heating coil is provided. Iron portions having continuity are formed on upper surfaces of the upper low temperature mold and the upper high temperature mold, recesses having continuity are formed on the upper surfaces of the lower low temperature mold and the lower high temperature mold, and the upper high temperature mold is mounted on the upper high temperature mold. It is preferable that an upper assembly groove is formed, and the lower low temperature mold is formed with a lower assembly groove on which the lower high temperature mold is seated.

In addition, the upper low temperature mold is preferably formed with an upper mounting groove for seating the upper blocking member, the lower low temperature mold is preferably formed with a lower mounting groove for seating the lower blocking member. The upper mounting groove may include a plurality of upper vertical mounting grooves formed to correspond to the size of the upper blocking member in the upper low temperature mold in contact with the sidewall of the upper high temperature mold, and a plurality of protruding upper upper molds in contact with the upper portion of the upper high temperature mold. An upper horizontal mounting groove into which the upper blocking member is inserted between the protruding ribs, and the lower mounting groove is a lower vertical mounting groove formed to correspond to the size of the lower blocking member in the lower low temperature mold in contact with the side wall of the lower high temperature mold; And a lower horizontal mounting groove into which the lower blocking member is inserted between the plurality of protruding ribs protruding from the lower low temperature mold contacting the lower high temperature mold.

The hot stamping molding method according to the present invention comprises the steps of preparing a mold having a high temperature region to maintain 300 ~ 500 ℃ and a room temperature region to maintain 20 ~ 80 ℃, the heat treatment object heated in a heating furnace to the prepared mold And a step of pressurizing and heat-treating the heat-treatment object put into the mold by forming a soft region and a high-strength region in the heat treatment object by the high temperature region and the normal temperature region of the mold.

The flexible region of the heat treatment object has a mixed structure of ferrite and pearlite, and the high strength region of the heat treatment object has a martensite structure. The mold is composed of an upper mold having a convex portion for pressing the heat treatment object and a lower mold having a recess, the upper mold is an upper low temperature mold, an upper high temperature mold assembled to the upper low temperature mold, and for thermal cutoff And an upper blocking member disposed between the upper low temperature mold and the upper high temperature mold, wherein the lower mold includes a lower low temperature mold, a lower high temperature mold assembled to the lower low temperature mold, and the lower low temperature mold and a lower portion for thermal cutoff. It is preferable to include a lower blocking member disposed between the high temperature mold.

According to the present invention, the following remarkable effects can be realized.

First, the present invention has the advantage that by locally heating and cooling the upper mold and the lower mold, the appearance quality of the molded article can be improved, and the quality variation of the molded articles can be minimized.

Second, the present invention has the advantage that by forming a flexible region and a high-strength region in the vehicle component that is the heat treatment target, it can effectively absorb the collision energy through the deformation of the component during the vehicle collision, and protect the passengers from the vehicle collision safely.

Third, since the present invention does not separately use a rain force of a high-strength material for strength reinforcement, there is an advantage that it is possible to improve the motor performance and fuel economy by reducing the weight of the vehicle parts.

1 is a perspective view showing a hot stamping forming apparatus for local strength control according to the present invention.
Figure 2 is an exploded perspective view showing the upper mold of the hot stamping forming apparatus for local strength control according to the present invention.
Figure 3 is an exploded perspective view showing a lower mold of the hot stamping forming apparatus for local strength control according to the present invention.
Figure 4 is a state diagram showing the installation state of the hot stamping forming apparatus for local strength control according to the present invention.
Figure 5a is a photograph showing the mold of the hot stamping forming apparatus for local strength control according to the present invention.
5b is a graph according to an embodiment of a hot stamping forming apparatus for local strength control in accordance with the present invention;
Figure 6 is a schematic view showing a hot stamping process according to the prior art.

First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a hot stamping forming apparatus for local strength control according to the present invention.

As shown in FIG. 1, the hot stamping molding apparatus according to the present invention forms a flexible region and a high strength region on a heat treatment object through a locally heated mold, thereby implementing local strength control on the heat treatment object.

In order to implement this, the hot stamping molding apparatus includes an upper mold 100 and a lower mold 200 in which local heating is performed.

The upper mold 100 is for molding by pressing the upper surface of the heat treatment object injected into the mold, the iron portion corresponding to the upper surface of the heat treatment object is formed on the lower surface. Here, the heat treatment object is a component such as a vehicle body panel which is molded so as to be assembled with the vehicle body. In this embodiment, a bronze plate is used.

Figure 2 is an exploded perspective view of the upper mold of the hot stamping forming apparatus for local strength control according to the present invention.

As shown in FIG. 2, the upper mold 100 is configured by assembling the upper low temperature mold 110 and the upper high temperature mold 120. At this time, since the upper mold 100 is disassembled and assembled into the upper low temperature mold 110 and the upper high temperature mold 120, only a corresponding part can be replaced even in case of partial breakage due to heat change and the upper low temperature mold 110 and Installation of the upper blocking member 130 for the thermal cutoff between the upper high temperature mold 120 can be made easily.

The upper low-temperature mold 110 is provided with a cooling channel for cooling when forming a product therein, a portion of the convex portion is formed on the lower surface, and the upper assembly groove 112 for assembling the upper high-temperature mold 120 on one side thereof. Is formed.

Cooling channels of the upper low-temperature mold 110 to cool the temperature of the mold to maintain the mold temperature in the room temperature region of 20 ~ 80 ℃, for this purpose, a plurality of cooling channels are arranged spaced apart in the longitudinal direction of the upper low-temperature mold (110). Temperature control may be made through a separate cooler 400. The cooler 400 allows the low temperature cooling water to circulate through the cooling channel to prevent the temperature rise of the mold.

The upper high temperature mold 120 is assembled to the upper assembly groove 112 of the upper low temperature mold 110 to form a single upper mold 100 and a heating coil 320 for maintaining the mold at a high temperature at a predetermined temperature therein. ) Is provided and the other part of the convex portion is formed on the lower surface.

The heating coil 320 of the upper high temperature mold 120 maintains the temperature of the mold at a high temperature range of 300 to 500 ° C., and is connected to a separate temperature controller 300 to maintain the temperature constant. The temperature controller 300 detects the temperature of the mold through a detector (not shown), and then operates or stops the heating coil 320 to compensate the measured temperature detected by the detector to a target temperature. Adjust to maintain at 500 ° C.

The upper blocking member 130 is coupled between the upper low temperature mold 110 and the upper high temperature mold 120. The upper blocking member 130 is to effectively block heat transfer between the upper low temperature mold 110 and the upper high temperature mold 120. In this embodiment, a hemit plate which is an asbestos insulation material is used.

The hemid plate is formed by pressing and molding materials such as aluminum oxide and silicon dioxide, which are high-temperature, natural inorganic raw materials, at high pressure, and have mechanical strength and are easy to process. This hemid plate has the advantage that it can be used where heat resistance, nonflammability, arc resistance and high mechanical strength are required.

Preferably, the upper blocking member 130 is seated in the upper mounting groove 111 formed in the upper low temperature mold (110).

The upper mounting groove 111 is an upper vertical mounting groove 111 a formed in the upper low temperature mold 110 in contact with the sidewall of the upper high temperature mold 120, and an upper low temperature mold 110 in contact with the upper portion of the upper high temperature mold 120. It is composed of a plurality of upper horizontal mounting groove (111b) and a support step (111c) provided between the plurality of upper horizontal mounting groove (111b). The upper vertical mounting groove 111a is formed to be concave to correspond to the size of the upper blocking member 130, and the upper horizontal mounting groove 111b is provided with a plurality of protruding ribs 111c protruding perpendicular to the upper low temperature mold 110. It forms a space in which the upper blocking member 130 is inserted.

Figure 3 is an exploded perspective view of the lower mold of the hot stamping forming apparatus for local strength control according to the present invention.

As shown in FIG. 3, the lower mold 200 is for molding while supporting the lower surface of the heat treatment object injected into the mold, and is disposed below the upper mold 100 so as to correspond to the upper mold 100 described above. .

The lower mold 200 is configured by the lower low temperature mold 210 and the lower high temperature mold 220 assembled to each other, and correspond to the lower surfaces of the heat treatment targets on the upper surfaces of the lower low temperature mold 210 and the lower high temperature mold 220. The recessed portion is formed. Here, since the lower mold 200 is disassembled and assembled into the lower low-temperature mold 210 and the lower high-temperature mold 220, only a corresponding part can be replaced even in case of partial breakage due to heat change, and the lower low-temperature mold 210 and Installation of the lower blocking member 230 for the thermal cutoff between the lower high temperature mold 220 can be made easily.

The lower low temperature mold 210 is provided with a cooling channel for cooling when forming a product therein, the cooling channel of the lower low temperature mold 210 together with the cooling channel of the upper low temperature mold 110, the mold temperature is 20 ~ Keep at room temperature of 80 ℃. A portion of the recess is formed on the lower surface of the lower low temperature mold 210. The recess of the lower low temperature mold 210 together with the recess formed on the lower high temperature mold 220 constitutes the entire recess of the lower mold 200. The lower low temperature mold 210 has a lower assembly groove 212 for assembling the lower high temperature mold 220.

The lower high temperature mold 220 is provided with a heating coil 320 for maintaining a temperature higher than a predetermined temperature therein, the heating coil 320 of the lower high temperature mold 220 is a heating coil of the upper high temperature mold 120 ( 320), the mold temperature is maintained in a high temperature range of 300 ~ 500 ℃.

The lower blocking member 230 is coupled between the lower low temperature mold 210 and the lower high temperature mold 220. The lower blocking member 230 is seated in the lower mounting groove 211 formed in the lower low temperature mold 210.

The lower mounting groove 211 is a lower vertical mounting groove 211a formed in the lower low temperature mold 210 in contact with one side of the lower high temperature mold 220 and the lower low temperature mold 210 in contact with the bottom of the lower high temperature mold 220. It is composed of a plurality of lower horizontal mounting groove 211b formed in the) and the support jaw 211c provided between the plurality of lower horizontal mounting groove 211b. The lower vertical mounting groove 211a is formed to be concave to correspond to the size of the lower blocking member 230, and the lower horizontal mounting groove 211b is provided with a plurality of lower protruding ribs 211c protruding perpendicular to the lower low temperature mold 210. The space between the lower blocking member 230 is formed between the ().

In the above, a heating coil 320 and a cooling channel for implementing localized heating are respectively provided with the upper mold 100 and the lower mold 200, and the mold structure in which the high temperature region and the room temperature region are disposed on the upper and lower sides of the heat treatment object, respectively. Although described, the heating coil 320 and the cooling channel may be selectively installed in the upper mold 100 or the lower mold 200 as needed.

4 is a view showing an installation state of the hot stamping forming apparatus for local strength control according to the present invention.

As shown in FIG. 4, the upper mold 100 and the lower mold 200 described above implement press molding through a press configuration such as a bolster 510, a slider 520, and a mold holder.

For example, the upper mold 100 and the lower mold 200 are installed to face up and down through a mold holder, and after the heat treatment object (bronze steel sheet) heated in the heating furnace is moved to the upper portion of the lower mold 200, the bolster When the upper mold 100 is lowered through the 510 and the slider 520 to press the bronze plate, one side forms a soft zone while cooling the high temperature by the upper high temperature mold 120 and the lower high temperature mold 220. On the other side, the low temperature cooling is performed by the upper low temperature mold 110 and the lower low temperature mold 210 to form a high strength region.

In this case, the flexible region of the Bron steel sheet has a soft strength of about 800 Mpa while being composed of a ferrite and pearlite mixed structure, and the high strength region of the Bron steel sheet has a high strength of about 1500 Mpa or more as it is transformed into a martensite structure.

5A is a photograph showing a mold of a hot stamping molding apparatus for local strength control according to the present invention, and FIG. 5B is a graph showing an embodiment of a hot stamping molding apparatus for local strength control according to the present invention.

As shown in Figure 5a and Figure 5b, in the present embodiment, after determining the separation point from 1 to 30 in the longitudinal direction to the produced mold, the results of the micro-Vickers hardness (Hv) measurement at the point shown in Table 1 Measured at

Spacing
point One 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Hv 453 461 468 473 434 460 456 434 443 443 470 444 447 432 468 Spacing
point 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 Hv 466 466 449 529 435 435 444 446 450 464 265 218 228 239 216

Based on the boundary line (L), one side of the Bron steel sheet cooled to 300 ~ 500 ℃ becomes a soft region of about 800Mpa having a mixed structure of ferrite and pearlite while being cooled at a high temperature, and rapidly cooled to 20 ~ 80 ℃ The other side of the steel sheet is quenched at a low temperature and becomes a high strength region of about 1500 Mpa or more having a martensite structure.

Meanwhile, the hot stamping molding method for implementing local strength control using the aforementioned hot stamping molding apparatus will be described in more detail.

The hot stamping molding method according to the present invention comprises the steps of preparing a mold having a high temperature region to maintain 300 ~ 500 ℃ and a room temperature region to maintain 20 ~ 80 ℃, and input the heat treatment object heated in the heating furnace to the prepared mold And pressurizing and heat-treating the heat-treatment object to form the soft region and the high-strength region, respectively.

Specifically, in the preparing of a mold having a high temperature region and a room temperature region, the upper mold 100 and the lower mold 200 having the cooling channel and the heating coil 320 are disposed to face up and down.

Since the heating coil 320 is located on one side of the upper mold 100 and the lower mold 200, a high temperature region of 300 ~ 500 ℃ is formed, and the cooling channel on the other side of the upper mold 100 and the lower mold 200 Because it is located, a room temperature region of 20 ~ 80 ℃ is formed. In addition, since the details of the upper mold 100 and the lower mold 200 overlap with the contents of the upper mold 100 and the lower mold 200 described in the above-described hot stamping molding apparatus, a description thereof will be omitted. Let's do it.

In the step of injecting the heat treatment object into the prepared mold, the heat treatment object (bronze steel sheet) heated in the heating furnace is moved to the upper portion of the lower mold 200 that is inside the mold, to complete the preliminary work for press molding.

In this embodiment, a bronze plate heated to about 930 ° C. in a heating furnace is introduced into the mold. Preferably, by reducing the time required to transfer the bronze sheet to the inside of the mold in the furnace, the high strength during quenching of the bronze sheet is effectively achieved.

Pressing and heat-treating the heat treatment object, the upper mold 100 is lowered to press-form the bronze steel sheet, while simultaneously cooling one side of the bronze steel sheet to 300 ~ 500 ℃ and quenching the other side of the bronze steel sheet to 20 ~ 80 ℃ . Here, the reason for cooling the one side of the bronze steel sheet to 300 ~ 500 ℃, when cooling one side of the bronze steel sheet to 300 ℃ or less, the cooling rate of the bronze steel sheet is increased to have a strength of about 900MPa or more higher than the target strength, collision energy The disadvantage is that the absorption capacity of the decrease occurs, and if one side of the bronze steel sheet is cooled to 500 ℃ or more, the cooling rate of the bronze steel sheet is lowered to have a strength of less than 700MPa lower than the target strength. In addition, if the other side of the bronze steel sheet is not quenched at 20 to 80 ° C., a high strength region of about 1500 Mpa or more having a martensite structure is not generated.

As described above, since the formed heat treatment object, for example, a bronze plate constituting the vehicle part, may simultaneously form a flexible region and a high strength region, the collision energy may be effectively absorbed through deformation of the flexible region of the vehicle component during a vehicle crash. .

Although the present invention has been described in detail using the preferred embodiments, the scope of the present invention is not limited to the specific embodiments, and should be interpreted by the appended claims. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

100: upper mold 110: upper low temperature mold
120: upper high temperature mold 130: upper blocking member
200: lower mold 210: lower low temperature mold
220: Lower high temperature mold 230: Lower blocking member

Claims (8)

The upper low temperature mold 110, the upper high temperature mold 120 assembled to the upper low temperature mold 110, and the upper block disposed between the upper low temperature mold 110 and the upper high temperature mold 120 for thermal cutoff. An upper mold 100 including a member 130;
A lower low temperature mold 210, a lower high temperature mold 220 assembled to the lower low temperature mold 210, and a lower block disposed between the lower low temperature mold 210 and the lower high temperature mold 220 for thermal cutoff. A lower mold 200 including a member 230;
A sensing unit for sensing a temperature of the upper high temperature mold 120 and the lower high temperature mold 220; And
And a temperature controller 300 for adjusting the temperature of the upper high temperature mold 120 and the lower high temperature mold 220 so that the measured temperature sensed by the detection unit is compensated with a target temperature. Hot stamping forming equipment. The method according to claim 1,
Inside the upper low temperature mold 110 and the lower low temperature mold 210 is provided with a cooling channel for maintaining the mold 20 ~ 80 ℃,
The inside of the upper high temperature mold (120) and the lower high temperature mold (220) hot stamping apparatus for local strength control, characterized in that the heating coil 320 for maintaining the mold at 300 ~ 500 ℃ is provided. The method according to claim 1,
Convex portions having continuity are formed on upper surfaces of the upper low temperature mold 110 and the upper high temperature mold 120, and recessed portions having continuity are formed on upper surfaces of the lower low temperature mold 210 and the lower high temperature mold 220.
The upper low temperature mold 110 is formed with an upper assembly groove part 112 on which the upper high temperature mold 120 is seated, and the lower low temperature mold 210 has a lower assembly groove part on which the lower high temperature mold 220 is seated ( 212) is formed, hot stamping forming apparatus for local strength control. The method according to claim 2,
The upper low temperature mold 110 is formed with an upper mounting groove 111 on which the upper blocking member 130 is seated, and the lower low temperature mold 210 is mounted on a lower side with the lower blocking member 230 seated thereon. Hot stamping apparatus for local strength control, characterized in that the groove 211 is formed. The method of claim 4,
The upper mounting groove 111 is an upper vertical mounting groove (111a) formed to correspond to the size of the upper blocking member 130 in the upper low temperature mold 110 in contact with the side wall of the upper high temperature mold 120, And an upper horizontal mounting groove 111b into which the upper blocking member 130 is inserted between the plurality of upper protruding ribs 111c protruding vertically of the upper low temperature mold 110 in contact with the upper portion of the upper high temperature mold 120. ,
The lower mounting groove 211 is a lower vertical mounting groove 211a formed to correspond to the size of the lower blocking member 230 in the lower low temperature mold 210 in contact with the side wall of the lower high temperature mold 220, and the And a lower horizontal mounting groove 211b into which the lower blocking member 230 is inserted between the plurality of lower protruding ribs 211c protruding from the lower low temperature mold 210 in contact with the lower portion of the lower high temperature mold 220. Hot stamping forming apparatus for local strength control. Preparing a mold having a high temperature region for maintaining 300 to 500 ° C. and a room temperature region for maintaining 20 to 80 ° C .;
Injecting a heat treatment object heated in a heating furnace into the prepared mold; And
Pressing and heat-treating the heat treatment object put into the mold so that the flexible region and the high strength region are formed in the heat treatment object by the high temperature region and the normal temperature region of the mold; hot stamping for local strength control, comprising: Molding method. The method of claim 6,
The flexible region of the heat treatment object has a mixed structure of ferrite and pearlite, the high strength region of the heat treatment object has a martensite structure, hot stamping molding method for local strength control. The method of claim 6,
The mold is composed of an upper mold 100 having a convex portion for pressurizing the heat treatment object and a lower mold 200 having recesses.
The upper mold 100 has an upper low temperature mold 110, an upper high temperature mold 120 assembled to the upper low temperature mold 110, and the upper low temperature mold 110 and the upper high temperature mold 120 for thermal cutoff. Including a top blocking member 130 disposed between,
The lower mold 200 includes a lower low temperature mold 210, a lower high temperature mold 220 assembled to the lower low temperature mold 210, and a lower low temperature mold 210 and a lower high temperature mold 220 for thermal cutoff. Hot stamping molding method for local strength control, characterized in that it comprises a lower blocking member 230 disposed between.

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