DE102006053819A1 - Production of a steel component used in the chassis construction comprises heating a sheet metal part and hot press quenching the heated sheet metal part - Google Patents

Abstract

Production of a steel component comprises heating a sheet metal part to a temperature lying between the Ac1 and the Ac3 temperature of the steel and hot press quenching the heated sheet metal part so that the component has a structure in which the components are present as ferrite and martensite. The steel of the sheet metal part contains (in wt.%) 0.10-0.45 carbon, 0.05-0.50 silicon, 0.8-1.7 manganese, 0.05-0.6 chromium, maximum 0.015 phosphorus and maximum 0.003 sulfur. An independent claim is also included for a steel component produced by the above process.

Description

The The invention relates to a method for producing a high-strength Component with improved elongation at break by hot press hardening and a high-strength component with improved elongation at break and toughness.

At the Hot-press hardening of sheet metal blanks divided by cold or hot rolled steel strip are, the sheet metal blanks to a deformation temperature heated and in the heated Condition placed in the tool of a forming press. In the course of the subsequent transformation learns the sheet metal blank or the molded part from it by the contact with the cool tool a quick cooling, resulting in hardness in the component. supports can be fast cooling thereby by actively cooling the tool itself.

As in the article "Potential for lightweight body construction", published in the trade fair newspaper of Thyssenkrupp Automotiv AG for the 61st International Motor Show in Frankfurt, 15.-25. September 2005 , hot press hardening is reported to be used in practice, in particular for the manufacture of high-strength boron-alloyed steel body components. A typical example of such a steel is the steel known under the name 22MnB5, which can be found in the steel key 2004 under the material number 1.5528.

A steel comparable to steel 22MnB5 is made of JP 2006104526 A known. This known steel contains in addition to Fe and unavoidable impurities (in wt .-%) 0.05-0.55% C, max. 2% Si, 0.1-3% Mn, max. 0.1% P and max. 0.03% S. To increase the hardness, additional amounts of 0.0002-0.005% B and 0.001-0.1% Ti can be added to the steel. The respective Ti content serves for setting the nitrogen present in the steel. In this way, the boron present in the steel can develop its strength-increasing effect as completely as possible.

According to the JP 2006104526 A be produced from the composite steel thus first sheets, which are then preheated to above the Ac ₃ temperature, typically in the range of 850-950 ° C, temperature. In the subsequent cooling in the pressing tool, starting from this temperature range, the martensitic microstructure ensuring the desired high strengths is formed in the component molded from the respective sheet metal blank. Favorably, it has the effect that the sheet metal parts heated to the stated temperature level can be shaped to complex-shaped components at relatively low forming forces. This is especially true for such sheet metal parts, which are made of high-strength steel and provided with a corrosion protection coating.

The to the above explained Way of boron-alloyed steels produced components reach strengths of more than 1500 MPa. However, that has needed Completely martensitic structure As a result of the components, the components are insufficient for many applications Residual breaking strain of 5-6 have.

The relatively low residual elongation at break is with a low toughness associated. This leads in applications where there is a good deformation behavior arrives in the event of a crash, in addition to components that from the known boron-alloyed steels manufactured in the known manner, this requirement is often not to fulfill more can. This especially applies when it comes to the components to be produced around parts for an automobile body.

Of the The invention was therefore based on the object to provide a method which makes it possible to produce complex shaped steel components, the on the one hand a sufficiently high strength and good elongation at break and on the other hand have sufficient toughness to the in to meet the requirements of the practice. Furthermore If a component should be specified, its property spectrum on the one hand under normal conditions a high dimensional stability and on the other hand Ensures a high energy absorption capacity in an accident.

In Relative to the method is the above task solved by the subject matter of claim 1. Advantageous embodiments This method is indicated in the claims appended to claim 1.

In With respect to the component is the above task by the subject matter of claim 8 has been solved. Advantageous embodiments this component are specified in the dependent claims on claim 8.

The Invention is based on the fundamental idea a complete martensitic hardening of the component during press hardening to avoid. Instead, according to the invention in each case to produce, according to the invention procured Component a mixed structure produced, on the one hand a surprising high strength and on the other hand high elongation values and one for each Application sufficient toughness of the component according to the invention guaranteed.

To achieve this, erfindungsge according hot pressed sheet metal parts, which are produced from a steel known in terms of its composition. Its alloy contents (C: 0.10-0.45%, Si: 0.05-0.50%, Mn: 0.8-1.7%, Cr: 0.05-0.6%, P: max 0.015%, S: 0.003% maximum, and optionally one or more of the following alloying elements Al: 0.01-0.05%, N: 0.002-0.005%, Ti: 0.01-0.1%, B: 0.0008-0.008%, balance iron and unavoidable impurities, in% by weight) are coordinated so that it inherently has a high strength potential.

Unlike in the prior art, however, the sheet metal part made of this steel according to the invention is heated only to a temperature at which the austenitization is not yet completed. Rather, a heating temperature is selected according to the invention for the press-hardening, which is between the Ac ₁ and Ac ₃ temperatures determined for the respective steel (Ac ₁ temperature: temperature at which the transformation into austenite begins: Ac ₃ temperature: temperature, where conversion to austenite is completed). At these heating temperatures, the sheet processed in each case has a mixture of austenite and ferrite.

According to the invention Thus, only a "partial austenitization" of the sheet metal part takes place, at the time of the warming up existing ferrite structure of the each processed sheet to one for the properties of the obtained Component crucial share is maintained.

in the Course of the invention made Teilaustenitisierung the respective sheet metal part are thus only the structural components the carbon-rich phases such as perlite, bainite, martensite and cementite converted into austenite. Dependent from the chosen one temperature level Partial austenitization is also being transformed into part of the Sheet metal part originally Existing ferrite in austenite.

The warming However, the sheet metal parts according to the invention is always controlled so that after the warming present in the sheet metal part ferrite and austenite side by side. The respective Size of the shares on ferrite and austenite can be controlled via the heating temperature become.

at the subsequent press hardening in accordance with the invention heated Sheet metal transforms the austenitic structure into martensite. This Martensite content ensures high strength in the finished component. On the other hand is the one after heating in the sheet existing ferrite even after press hardening in Component still obtained and ensures the desired high elongation at break and improved toughness.

There the carbon content in austenite in the partial austenitization according to the invention each significantly higher is the total carbon content of the steel (for example is at a structure each with 50% austenite and 50% ferrite, the C content of austenite about twice as high as the C content of the steel as a whole) remains the austenite to press hardening essentially stable. This allows a safe process management while the press hardening.

at inventive approach is Consequently, in the respectively obtained component targeted a microstructure set, which is similar to that of dual-phase steels. About the Size of the shares of martensite and ferrite can be adjusted directly, whether produced according to the invention Component the strength, elongation at break and / or toughness is in the foreground.

In the procedure according to the invention, the formation of the proportions of martensite is influenced directly by the choice of a suitable heating temperature. Heating temperatures lying close to the Ac ₃ temperature lead in the finished component to larger martensite proportions and thus higher strength, while particularly good elongation values can be achieved by lower heating temperatures close to the Ac ₁ temperature.

The Expansion characteristics of a component produced according to the invention are always greater than the corresponding values for a manufactured in a known manner Component can be determined with vollmartenitisiertem microstructure. So can be in accordance with the invention easily and selectively produce high-strength components whose breaking elongation is around up to twice larger as the breaking elongation of a component produced in a known manner.

With The invention thus has a possibility to disposal, for their Practical application machines are needed in comparison are less expensive to the previously known variants of hot forming and thus trigger lower procurement and maintenance costs. The Savings are not only due to the significantly reduced Requirements for the the warming of the sheet metal part needed Heat source but also achieved by the lesser requirements, the the forming tool can be made. By the invention lower Temperatures is the cooling load minimized in the tool. About that can out Components according to the invention depending on the strength class with conventional cutting tools be circumcised. The expensive laser cutting of the components obtained can be omitted.

One particular advantage of the invention is that in accordance with the procedure of the invention Produce components that provide an optimal combination of strength and have extensibility. Compared to the known measures for setting a certain strength and extensibility level, such as the subsequent Tempering conventionally press-hardened components offers the Invention another potential savings. Thus, according to the invention, hot-press hardened components reach a strength level that is that of conventionally press-hardened and subsequently tempered at temperatures of 300-400 ° C Components with complete martensitic structure equivalent. At the same time, the elongation values are generated according to the invention However, components are much higher than the conventionally press-hardened and tempered components. Therefore, with the product produced according to the invention is minimized Production expenditure a component available, that a the state of the Technique superior feature combination from high strength and very good elongation properties.

The inventive method is suitable for processing sheet metal parts made of hot or cold-rolled steel strips are won. If necessary, the relevant steel strips may be used the hot press hardening carried out according to the invention surface finishing be subjected. In the course of this surface refinement they can for example, flame-aluminized (eg, coating with an AlSi (AS) or AlZn layer (AZ)), hot-dip galvanized (eg coating with a simple zinc (Z), a zinc iron (ZF) or a zinc aluminum layer (ZA)) or with an organic-inorganic coating (eg a lacquer coating, on the one hand a corrosion protection and on the other hand an improvement causes the tribological properties of the board during press hardening) be provided. The use of surface-treated sheet metal parts has just completed of hot press curing the advantage that the applied to the base substrate coating an excessive scale formation on the sheet metal part prevented by the result of the press molding would be worsened.

So long ensures a sufficiently rapid cooling in the hot-pressing tool is the success achieved by the invention regardless of like hot press hardening yourself. Accordingly, in the context of the invention, the hot molding press hardening can be done directly or indirectly become. In direct thermoforming press hardening, the sheet metal part is a Board used, which is heated in accordance with the invention and from then directly, d. H. without further deformation steps the respective component is formed. In the case of indirect hot-pressing hardening, on the other hand becomes in any one step from a sheet metal plate an arbitrarily shaped Sheet metal preformed. This preformed sheet metal part is then in according to the invention heated and receives at the subsequent Hot press forming step its final Shape.

To the inventively in the range of Ac ₁ - to Ac ₃ temperatures carried out heating of each thermosetting sheet metal part may be followed by cooling to the entry into the hot press tool so that with the onset of the forming process in the sheet metal part in each case with regard to the respective work result optimal temperature is. This cooling can take place, for example, in the course of workpiece transfer from the heating device to the pressing tool in air or under a protective gas, by which a scaling of the surface of the sheet metal part to be prevented.

One Component according to the invention is characterized by the fact that it consists of a steel, the in addition to iron and unavoidable impurities (in% by weight) C: 0.10-0.45%, Si: 0.05-0.50%, Mn: 0.8-1.7%, Cr: 0.05-0.6%, P: max. 0.015%, S: max. 0.003%, and optionally one or more the following alloying elements Al: 0.01-0.05%, N: 0.002-0.005%, Ti: 0.01-0.1%, B: 0.0008-0.008%, where the component a mixed structure with fractions of ferrite and martensite and at an elongation at break A80 of 6-14% a tensile strength of 800-1500 MPa owns.

Prefers are the proportions of martensite and ferrite in the structure of the component according to the invention matched so that it has a tensile strength of 800-1100 MPa has. Such a component fulfills most of the requirements the practice in terms of its strength requirements and at the same time has an optimized toughness.

One by adjusting the corresponding proportions of martensite and ferrite in its structure optimally adjusted inventive component is characterized in that its breaking elongation A80 is in the range of 10-14%.

Due to their special property profile, components according to the invention are suitable in particular for use as parts of vehicle bodies. Thus, components according to the invention can easily be shaped so that they can be used as crash-relevant components in an automobile body, on the one hand ensure sufficient rigidity of the respective body, but at the same time should be able to safely in an accident accidental kinetic energy in deformation energy convert. Accordingly, in the manner according to the invention, preference may be given to bumper intensifiers kings, A-, B-, C- and D-pillars and reinforcements, sills, roof frames, side members, tunnel reinforcements, side impact cushions and car body mounting plates intended for these columns.

Inventive components become self-evident particularly preferably produced by the process according to the invention. This not only allows easy customization of the property profile of the respective component to its intended use, but thereby enables that the sheet metal parts according to the invention before their Warmpresshärtung only on a low heating temperature compared to the prior art, a particularly cost-effective Production of high-strength components with a toughness similar to that of conventional produced, purely martensitic components clearly superior is. It turns out that the components produced according to the invention due to the composition of the steel used in the invention and the special processing path also a high bake-hardening potential own, which is an additional Increasing the strength of inventive components allows.

following The invention will be explained with reference to an embodiment.

The attached diagram schematically shows the principle underlying the method according to the invention. On the left side of the diagram, a section of the iron-carbon diagram prepared for a manganese-boron steel is shown, while on the right side of the diagram, the temperature profile over the respective steps of the method according to the invention can be seen. Accordingly, the respective sheet metal part is first heated within a time t1 to a heating temperature TE lying between the Ac ₁ and the Ac ₃ temperature of the carbon content X-containing steel from which it is produced. Subsequently, it is kept at the heating temperature TE over a time t2 sufficient for the desired partial austenitization. This is followed within a time t3, the transfer to the hot press tool, within which the sheet metal part cools in air to a still lying above the Ac ₁ temperature deformation temperature TV. With this temperature, the sheet metal part is placed in the hot pressing tool in which it is then cooled within a short time t4 quickly to a temperature of less than 100 ° C, converting the austenite formed during partial austenitization in martensite.

• – Stahlerzeugung mit Konverter;
• – Vergießen des Stahls durch konventionellen Strangguss oder in einer Gießwalzanlage zu einem Vormaterial, wie Gramme oder Dünnbramme, wobei der Einsatz einer Gießwalzanlage bevorzugt ist;
• – Warmwalzen bei einer 850–900°C betragenden Warmwalzendtemperatur;
• – Haspeln des erhaltenen Warmbands bei einer 560–600°C betragenden Haspeltemperatur;
• – erforderlichenfalls Beizen des Warmbands.

A typical process involving the invention of manufacturing components, which are particularly suitable for the construction of automobiles, can be described as follows:

• - steelmaking with converter;
• Casting of the steel by conventional continuous casting or in a cast roll mill to a starting material, such as logs or thin slab, wherein the use of a casting and rolling plant is preferred;
• Hot rolling at a hot rolling end temperature of 850-900 ° C;
• - Coiling the resulting hot strip at a reel temperature of 560-600 ° C;
• - If necessary, pickling of the hot strip.

has the hot strip already a for the later one Use of the component to be manufactured from it sufficient thickness and condition, so the hot strip at this point through Fire aluminizing (AS, AZ), hot dip galvanizing (Z, ZF, ZA) and / or organo-inorganic coating with a corrosion-protective coating or Oxidation be provided.

Otherwise takes place first cold rolling, which is preferably carried out without intermediate annealing, wherein the degree of cold rolling over 40% should be. The resulting cold strip can then also in the for the hot strip already described with one before corrosion or oxidation protective coating provided become.

From the hot strip or cold strip then sheet metal blanks are divided. The sheet metal blanks are then heated to a heating temperature between the Ac ₁ and Ac ₃ temperatures.

To one in the course of the transfer of the sheet metal blank from the respective heating furnace entering the press mold air cooling by a small amount of temperature The sheet metal blanks are placed in the hot press hardening tool in which they formed to the component and at the same time cooled so fast that the after heating in their structure existing austenite except for small retained austenite contents completely in Martensite converts.

The inventive method has been tested on a sheet metal part, as a flat shaped board from one in the manner described above from the known 22MnB5 steel produced cold strip has been divided. The 22MnB5 steel contains typically (in% by weight) 0.240% C, 1.3% Mn, 0.25% Si, max. 0.02% P, max. 0.005% S, 0.035% Al, 0.035% Ti, 0.155% Cr, 0.003% B as well each max. 0.1% of Mo, Cu and Ni, balance iron and unavoidable Impurities.

The corresponding composite sheet metal part has been heated in an oven to a heating temperature of 780 ° C, in which Sheet metal part a mixed structure of austenite / ferrite was present. Subsequently, the sheet metal part has been inserted by means of a conveyor in an actively cooled mold. During the transfer from the oven to the die, only a small amount of heat loss occurred, resulting in a temperature decrease of less than 5 ° C.

In the press mold, the sheet metal part is deformed into a component been that for an automobile body was intended. Due to the during the compression deformation incoming intensive contact of the sheet metal part with the press mold went along with the compression deformation cooling, the cooling rate with a quenching of the sheet metal part in an oil bath was comparable.

The after hot press hardening in accordance with the invention obtained automobile body component had a mixed structure, 63% ferrite, 30% martensite and 7% retained austenite duration. The for the final strength was 900 MPa, while its Elongation at break A80 was 13%.

Claims (10)

A method of manufacturing a component by hot press hardening a sheet metal part made of a steel including, in addition to iron and unavoidable impurities (in% by weight): C: 0.10-0.45% Si: 0.05-0.50 % Mn: 0.8-1.7% Cr: 0.05-0.6% P: max. 0.015% S: max. 0.003% and optionally one or more of the following alloying elements Al: 0.01-0.05% N: 0.002-0.005% Ti: 0.01-0.1% B: 0.0008-0.008%, characterized in that the sheet metal part for the hot press hardening is heated to a temperature lying between the Ac ₁ and the Ac ₃ temperature of the steel and that the thus heated sheet metal part, if necessary after an intermediate cooling, is hot press hardened, so that the component obtained after the hot pressing is a microstructure possesses, in the portions of ferrite and martensite are present. Method according to claim 1, characterized in that that the sheet metal part is separated from a hot strip. Method according to claim 1, characterized in that that the sheet metal part is separated from a cold strip. Method according to one of the preceding claims, characterized characterized in that the entering after the heating and before the hot press hardening Cooling done in air. Method according to one of the preceding claims, characterized characterized in that the sheet metal part before the hot press hardening a surface finishing is subjected. Method according to one of the preceding claims, characterized characterized in that the sheet metal part as a flat shaped board in is thermoformed a step to the component. Method according to one of claims 1 to 5, characterized that the sheet metal part is preformed in at least one step, and that the preformed sheet metal part is thermoformed to the component becomes. Component that consists of a steel next to iron and unavoidable impurities (in% by weight): C: 0.10-0.45% Si: 0.05-0.50% Mn: 0.8-1.7% Cr: 0.05-0.6% P: Max. 0.015% S: max. 0.003% and optionally one or more the following alloying elements Al: 0.01-0.05% N: 0.002-0.005% Ti: 0.01-0.1% B: 0.0008 to 0.008% contains, where the component a mixed structure with fractions of ferrite and martensite and at an elongation at break ABO of 6-14% a tensile strength of 800-1500 MPa owns. Component according to claim 8, characterized in that that it has a tensile strength of 800-1100 MPa. Component according to claim 8 or 9, characterized in that its breaking elongation A _{80 is} 10-14%.