DE102012111959A1 - Method for producing a motor vehicle component and motor vehicle component - Google Patents

Abstract

The present invention relates to a method and a method for producing a motor vehicle component and a motor vehicle component produced according to the invention. In particular, a sheet steel plate with a stacking fault energy between 10 and 40 mJ / m2 and a manganese content between 10 and 30% is provided for the production of the motor vehicle component, the active ingredient of which leads to the formation of twins at room temperature and at least partially has a predominantly austenitic structure. This sheet steel blank is at least partially tempered to a temperature between + 30 ° C and -250 ° C and then cold-formed. The method according to the invention, in particular, significantly increases the yield point and the tensile strength with high ductility at the same time.

Description

The present invention relates to a method for producing a motor vehicle component according to the features in claim 1.

The present invention further relates to a motor vehicle component according to the features in claim 12.

From the prior art it is known to produce self-supporting motor vehicle bodies from metallic components. For this purpose, motor vehicle pillars, rockers, roof rails or even longitudinal or transverse beams are first produced and then assembled into assemblies and then to the complete vehicle body.

In the course of the requirement for an economically operable motor vehicle, alternative materials have been used in comparison to steel in recent decades. Thus, for example, protruding motor vehicle bodies made of light metal, in particular made of aluminum. However, these are associated with high production costs due to expensive raw materials and complex processing methods.

Furthermore, more and more demands on the crash safety of a motor vehicle, with simultaneous cost pressure. Thus, a motor vehicle and thus also a motor vehicle body or other motor vehicle structural components or body components should be particularly light, have a high crash safety and at the same time be produced cheaply.

For this purpose, high-strength and ultra-high-strength steels have been developed in recent years, which are inexpensive to produce compared to light metals or fiber composites and at the same time have a particularly high stiffness and thus crash safety with low weight.

For example, it is thus possible through the hot forming and press-hardening technology to first heat curable steels above the austenitizing temperature and then to thermoform and harden them. This entails high strengths but limited ductility properties of the component. Under certain circumstances, elaborate heat aftertreatments are necessary in order to adjust ductility in specific areas.

An alternative to the hot-formed and press-hardened steels are so-called TWIP steels, in which an intensive mechanical twinning in austenitic steel occurs during plastic deformation. The process begins even at low load and solidifies the steel, with high elongation at break. The twin formation counteracts the dislocation movement like grain boundaries in the material structure and thus a further change of shape as resistance. The strain-induced twin formation causes a higher extensibility. Due to the martensitic areas results in a high strength at the same time.

For example, the production of such TWIP components from the DE 10 2010 020 373 A1 known.

The object of the present invention is, starting from the prior art, to show a manufacturing method and a motor vehicle component which can be produced efficiently, has a particularly low inherent weight and has a high degree of hardness combined with high ductility.

The aforementioned object is achieved by a method having the features in claim 1.

The objective part of the object is further achieved with a motor vehicle component according to the features in patent claim 12.

Advantageous embodiments of the present invention are the subject of the dependent claims.

• – Bereitstellen einer Stahlblechplatine mit einem Mangananteil von 10 bis 30% und einer Stapelfehlerenergie von 5 bis 50 mJ/m², insbesondere 10 bis 40 mJ/m², wobei der Werkstoff der Stahlblechplatine bei Raumtemperatur zur Zwillingsbildung neigt und zumindest partiell ein überwiegend austenitisches Gefüge aufweist,
• – Zumindest partielles Temperieren der Stahlblechplatine auf eine Kaltumformtemperatur zwischen +30°C und –250°C,
• – Umformen der Stahlblechplatine zu dem Blechbauteil bei im Wesentlichen Kaltumformtemperatur, wobei durch den Kaltumformvorgang zumindest partiell eine Martensitbildung induziert wird,
• – Entnahme des Blechbauteils.

The method according to the invention for the production of a metallic motor vehicle component is characterized by the following method steps:

• - Providing a steel plate with a manganese content of 10 to 30% and a stacking fault energy of 5 to 50 mJ / m ² , in particular 10 to 40 mJ / m ² , wherein the material of the sheet steel plate tends to twin at room temperature and at least partially a predominantly austenitic structure having,
• At least partial tempering of the sheet steel plate to a cold forming temperature between + 30 ° C and -250 ° C,
• Forming the sheet-steel plate to the sheet-metal component at a substantially cold-forming temperature, at least partially inducing martensite formation by the cold-forming process,
• - Removal of the sheet metal component.

According to the invention it is thus provided that a metallic component, in particular made of a high manganese-containing steel material, very particularly preferably made of a TWIP steel is provided with a predominantly austenitic structure. The component is then further cooled at a temperature substantially below room temperature, in particular between + 30 ° C and -250 ° C, most preferably between + 25 ° C and -200 ° C to a cold forming temperature. After the cooling, a cold forming of the cooled sheet steel plate to the desired sheet metal component takes place at the achieved cold forming temperature. The cold-formed component is then removed from the forming tool.

During the cold forming, plastic deformation results in a transformation of the essentially austenitic microstructure into an at least partially, preferably complete, martensitic microstructure. As a result, the strength properties of the component are increased accordingly. It is a deformation-induced martensite formation. This simultaneously causes the increase in hardness and formability in the case of plastic stress in the manufacture of the motor vehicle component and / or in the use of the motor vehicle component. A silicon fraction results in solid solution hardening, which increases the yield strength of the component. As a result of the plastic deformation, the metastable carbon-rich austenite is transformed into martensite induced by deformation, as a result of which the motor vehicle component is at least partially solidified by the twinning of the TWIP effect.

At the same time, however, the TRIP effect is utilized according to the invention, which causes a special martensite formation during forming. Here, in particular, the TRIP effect occurs in the case of deformation-induced martensite formation. The TRIP effect causes a simultaneous increase in hardness and formability under plastic stress. The TRIP effect is characterized in particular by the fact that as soon as the plastic area is reached during forming, the metastable carbon-rich austenite transforms into martensite induced by deformation. As a result, the steel is solidified during plastic deformation targeted.

Particularly preferred for the production of the motor vehicle component according to the invention, a steel alloy is used, which has the following alloy constituents expressed in weight percent: - carbon (C) Max. 2% - manganese (Mn) 10 to 30% - silicon (Si) Max. 6% - aluminum (Al) Max. 8th% - niobium (Nb) Max. 1% - silicon (Si) Max. 1% - titanium (Ti) Max. 1% Remaining iron (Fe) and impurities caused by melting.

By selective choice of the alloy components, matched to the cold forming temperature at which the component is formed, it is possible to set the motor vehicle component at least partially targeted with strength properties.

In particular, by cooling the sheet metal blank, the stacking fault energy is lowered such that the twin formation occurring due to the TWIP effect is reduced to a negligible level. At the same time, however, the transformation of the metastable austenite into martensite increases, which in turn increases the strength property of the component. In particular, a good strength property becomes achieved when the set degree of deformation of the component takes place at least locally except for the uniform expansion of the alloy material used.

Depending on the alloy composition used and the cold-forming temperature of the sheet-metal plate, the aim is to convert as much as possible austenitic structure into martensite by plastic deformation. Another control parameter is the degree of deformation itself. The higher the degree of deformation, the stronger the transformation of austenite into martensite.

Particularly advantageous strength properties have been found when a sheet metal blanks with a stacking fault energy between 5 and 50 mJ / m ² , in particular from 20 to 40 mJ / m ^{2 is used} as starting material and is then cooled to the cold forming temperature, in particular by cooling the stacking fault energy is selectively reduced within the sheet metal plate to a value between 15 and 20 mJ / m ² .

The cooling itself can be done with different cooling media, in particular liquid nitrogen is used. By means of the aid of the liquid nitrogen is in particular a cold working temperature between + 25 ° C and -200 ° C, most preferably to a cooling temperature in the range of + 25 ° C to -197 ° C. In the context of the invention, this disclosure means any temperature in the latter interval, ie in the range of + 25 ° C to -197 ° C as a cold forming temperature. Thus, it is possible to cool the component, for example to a cold forming temperature of -180 ° C but also -100 ° C or any value in the interval of + 25 ° C to -197 ° C. In particular, the sheet steel plate is pre-stretched at cold forming temperature.

In particular, the cooling or the tempering takes place at least partially within the scope of the invention. This makes it possible to selectively adjust the desired strength properties only partially within the component. The heat conduction within the sheet metal plate itself, for example, from a cooled region to a non-cooled region is negligible in the context of the invention by fast cooling times.

The cooling itself can be carried out in particular in a cooling station, wherein the cooled sheet metal plate is transferred after cooling in a forming tool, wherein the forming tool in turn, in turn itself is cooled. The deformation itself then takes place in the forming tool at substantially the cold forming temperature. A slight warming during the transfer and / or in the forming tool itself is again negligible within the scope of the invention.

In an alternative, it is possible that the metal sheet itself is cooled in the forming tool to the cold forming temperature and then directly cold formed.

Furthermore, in the context of the invention, it is alternatively also possible for the sheet metal blank to be preformed at least partially, in particular the preforming takes place at or above the room temperature. In the context of the invention, the preforming is thus carried out in particular in a range between 0 ° C and + 50 ° C, most preferably at + 20 ° C to + 30 ° C. Following this, the preformed sheet metal blank is then cooled to the cold forming temperature and then cold-formed.

Furthermore, it is preferably possible within the scope of the integration that the preformed regions are formed directly to a final dimension, wherein the cold forming subsequently takes place in different regions from the preformed regions. Consequently, furthermore, preferably only the non-preformed areas are tempered or cooled and then cold-formed. As a result, the preformed areas have a lower strength than the cold-formed areas.

In the context of the invention, however, it is also possible that specific areas are only partially preformed, wherein the preforming is carried out, for example, as Vorrecken, in particular at cold forming temperature. The Vorrecken itself can then be carried out again partially. The degree of deformation during pre-stretching is in particular 10 to 90% of the final dimension. In the context of the invention, it is again possible in turn to cool and cold-form the pre-stretched or preformed regions, wherein the degree of martensite formation is in turn specifically adjusted by the degree of preforming or pre-stretching.

Another component of the present invention is a motor vehicle component, which is produced by a method with at least one of the aforementioned features, wherein the motor vehicle component of a TWIP steel alloy is formed and according to the invention is characterized in that at least partial areas of the component have a substantially martensitic structure. The production process according to the invention therefore makes it possible to reduce the TWIP effect, and thus the mechanical twinning, while at the same time producing a higher martensite content in the regions which have been formed at cold forming temperature.

In particular, the motor vehicle component is formed of a steel alloy, which is preferably high manganese-containing and has the following alloy constituents expressed in weight percent - carbon (C) Max. 2% - manganese (Mn) 10 to 30% - silicon (Si) Max. 6% - aluminum (Al) Max. 8th% - niobium (Nb) Max. 1% - silicon (Si) Max. 1% - titanium (Ti) Max. 1% Remaining iron (Fe) and impurities caused by melting.

In particular, this is a TWIP steel alloy which, depending on the desired strength properties, is selected in the respective percentage proportion as well as the presence of the individual alloying elements.

As a result of the production method according to the invention, the motor vehicle component in the martensitic regions preferably has a yield strength Rp 0.2 between 500 and 1500 MPa, in particular between 700 and 1300 MPa, and very particularly preferably between 750 and 1000 MPa. In a partially produced component, the remaining regions then have a plugging limit between 200 and 800 MPa, in particular between 300 and 500 MPa.

Further preferably, the motor vehicle component has a tensile strength Rm between 500 and 1800 MPa, in particular between 800 and 1700 MPa, and very particularly preferably between 1000 and 1650 MPa. In a partially cooled and formed components, the remaining regions then have a tensile strength Rm of 500 to 1500 MPa, in particular from 800 to 1200 MPa and most preferably from 850 to 1100 MPa.

Further advantages, features, characteristics and aspects of the present invention are explained in the following description. The schematic figures are used for easy understanding of the invention. Show it:

1 a stress-strain diagram of a steel according to the invention at three different temperatures.

In the figures, the same reference numerals are used for the same or similar components, even if a repeated description is omitted for reasons of simplicity.

1 shows a stress-strain diagram of a steel formed according to the invention, wherein three different cold forming temperatures were selected. It can be seen that the lower the cold forming temperature has been chosen, the more the tensile strength increases. So the steel became the curve 1 at room temperature and thus at substantially 20 ° C formed. The material was in the curve 2 formed at -110.15 ° C and has a significantly higher tensile strength compared to the transformation at room temperature. The component according to the curve 3 was formed at -196.15 ° C and has a significantly increased tensile strength.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010020373 A1 [0009]

Claims (14)

A method for producing a metallic motor vehicle component, characterized by the following method steps: providing a steel sheet with a manganese content of 10 to 30% and a stacking fault energy of 5 to 50 mJ / m ² , in particular 10 to 40 mJ / m ² , the material of Sheet steel plate prone to twin formation at room temperature, at least partial tempering of the sheet steel plate to a cold forming temperature between + 30 ° C and -250 ° C, reshaping the steel sheet to the sheet metal component at substantially cold forming temperature, at least partially inducing martensite formation by the cold forming process, - Removal of the sheet metal component. A method according to claim 1, characterized in that a sheet steel plate is used, which is formed from a steel alloy having the following alloy constituents expressed in weight percent: - carbon (C) Max. 2% - manganese (Mn) 10 to 30% - silicon (Si) Max. 6% - aluminum (Al) Max. 8th% - niobium (Nb) Max. 1% - silicon (Si) Max. 1% - titanium (Ti) Max. 1% Remaining iron (Fe) and impurities caused by melting. A method according to claim 1 or 2, characterized in that a sheet steel plate is used from a TWIP steel. Method according to one of the preceding claims, characterized in that the predominantly austenitic structure is converted by the forming operation in martensitic structure. Method according to one of the preceding claims, characterized in that the steel sheet is cooled with a stacking fault energy of 20 to 40 mJ / m ² on the cold forming temperature, wherein the cooling reduces the stacking fault energy to 15 to 20 mJ / m ² . Method according to one of the preceding claims, characterized in that liquid nitrogen is used for cooling. Method according to one of the preceding claims, characterized in that the cold forming temperature between + 25 ° C and -200 ° C, in particular in the range of + 25 ° C and -197 ° C, in particular the sheet steel plate is pre-stretched at cold forming temperature. Method according to one of the preceding claims, characterized in that the cooling of the sheet steel plate takes place in a cooling station and the cooled steel sheet is transferred into a forming tool, wherein the forming tool is in particular cooled. Method according to one of the preceding claims, characterized in that the sheet steel plate is cooled in the forming tool to the cold forming temperature. Method according to one of the preceding claims, characterized in that the sheet steel plate is at least partially preformed, in particular preforming takes place at or above room temperature. Method according to one of the preceding claims, characterized in that the preformed areas are formed to final dimensions, wherein the cold forming then takes place in different areas of the preformed areas. Motor vehicle component, produced by a method according to at least claim 1, wherein the motor vehicle component is formed from a TWIP steel alloy, characterized in that at least partial areas of the component have a substantially martensitic structure. Motor vehicle component according to claim 12, characterized in that it comprises the following alloy constituents, expressed in percent by weight: - carbon (C) Max. 2% - manganese (Mn) 10 to 30% - silicon (Si) Max. 6% - aluminum (Al) Max. 8th% - niobium (Nb) Max. 1% - silicon (Si) Max. 1% - titanium (Ti) Max. 1% Remaining iron (Fe) and impurities caused by melting. Motor vehicle component according to claim 12 or 13, characterized in that the martensitic regions have a yield strength Rp0.2 between 500 and 1500 MPa, in particular between 700 and 1300 MPa and most preferably between 750 and 1000 MPa.

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