EP3122910A2

EP3122910A2 - Components made of a steel alloy and method for producing high-strength components

Info

Publication number: EP3122910A2
Application number: EP15741783.3A
Authority: EP
Inventors: Uwe Diekmann
Original assignee: Comtes FHT AS; Matplus GmbH
Current assignee: COMTES FHT A.S.; MATPLUS GMBH
Priority date: 2014-03-24
Filing date: 2015-03-24
Publication date: 2017-02-01
Also published as: WO2015144661A2; DE102014205392A1; US20170114426A1; US10253391B2; WO2015144661A3

Abstract

The invention relates to a component made of a steel alloy comprising iron and, as an alloying element, copper, in particular consisting (in wt% in relation to the total alloy, wherein the sum of all constituents equals 100 wt%) of iron ≥ 96, carbon 0.04 to 0.12, copper 0.5 to 2.0, manganese + silicon + chromium + nickel 0.5 to 2.5, titanium 0 to 0.1, boron 0 to 0.005, and typical unavoidable impurities. In the production of semi-finished products and of components, a combination of cold-working and annealing treatment below the recrystallization temperature is used in order to thus obtain advantageous properties with regard to strength and ductility.

Description

The invention relates to a component made of a steel alloy and to a method for its production. A component in the sense of the present invention may be a semi-finished product.

State of the art and technical background

Lightweight construction with high-strength steels enables cost and resource-efficient products. The strength of steels can be increased by solid solution hardening, transformation hardening, fine grain hardening, precipitation hardening and cold working. Usually, all of these mechanisms contribute to component strength.

Known is the so-called "steel banana", which represents the relationship between strength and elongation at break for different grades of steel, which is illustrated in FIG.1 (Source: ADVANCED HIGH STRENGTH STEEL (AHSS) APPLICATION GUIDELINES Version 4.1, www.worldautosteel.org) ,

In the publications "AJ DeArdo and RA Walsh," High strength low alloy steel ", US5352304 A04-Oct-1994" and "EJ Czyryca," Development of low-carbon, copper-strengthened HSLA steel plate for naval ship construction ", DTIC Document, 1990 "describes high-strength Cu-alloyed steels which are preferably used in shipbuilding in the hot-rolled and hardened state. The steel is additionally alloyed with nickel to reduce the red-rupture sensitivity and increase toughness. However, such high nickel contents can not be used for cost reasons in many markets and applications.

The possibility of using Cu to increase the strength of IF steel is described in the publication "R. Rana. W. Bleck, S. B. Singh, and O.N. Mohanty, "Development of high strength interstitial free steel by copper precipitation hardening," Mater. Lett., Vol. 61, No. 14, pp. 2919-2922, 2007 ". By adding copper, high strengths of 500-600 MPa are achieved. The document "R. Rana, SB Singh, and ON Mohanty, "Effect of composition and pre-deformation on aging hardening response in a copper-containing interstitial free steel", Mater. Charact., Vol. 59, No. 7. pp. 969-974, July 2008 "deals with investigations on the influence of pre-deformation on the precipitation and solidification behavior of a Cu-alloyed IF steel. Thus precipitation hardening is accelerated by a pre-deformation of more than 40%. The document "N. Maruyama, M. Sugiyama, T. Hara, and H. Tamehiro, "Precipitation and phase transformation of copper particles in low alloy ferritic and martensitic steels", Mater. Trans. JIM, vol. 40, pp. 268-277, 1999 "discloses that in a Cu-alloyed, ferritic, work-hardened material, the strength in an annealing treatment increases between 700 and 900 Kelvin. The influence of copper additions is for steel in the publication "R. Rana, W. Bleck, SB Singh, and ON Mohanty, "Hot Shortness Behavior of a Copper-alloyed High Strength Interstitial Free Steel," Mater. Eng. Eng. A, Vol. 588, pp. 288-298, Dec. 2013 "described.

In the publication "D. Isheim, MS Gagliano, ME Fine, and DN Seidman, "Interfacial segregation at Cu-rich preeipitates in a high-strength low-carbon steel studied on a sub-nanometer scale", Acta Mater., Vol. 54, No. 3, Pp. 841-849, Feb. 2006, "describes the use of an atomic probe (APT Atom Probe Tomography) for the analysis of Cu precipitates of a high strength steel for marine applications. Cu precipitates in steel are conventional not detectable by light microscopy and scanning electron microscopy, since the size of the precipitated particles is in the range of a few nanometers.

A tensile test for metallic materials is a standard procedure of material testing according to DIN EN ISO 6892. According to the invention, the material parameters are preferably also measured according to this DIN. An elongation at break A is a material characteristic which shows the permanent elongation of a sample after fracture, based on the initial measurement length. It characterizes the ductility (deformability) of a material. It is the permanent change in length related to the initial measurement length L _{0 of} a sample in the tensile test after a break.

The initial length L ₀ is determined before the tensile test by measuring marks on the tensile test. Due to the localized constriction, the elongation at break A is dependent on the initial measuring length L ₀ . To obtain comparable values for the elongation at break, proportional rods are used for tensile tests usually, that is samples where the initial gauge length L ₀ is the initial cross-section S ₀ in a fixed ratio.

For round bars, a value of k = 5 is common. The elongation at break is then called A5. In the tensile test, after the tensile strength R _{m has been reached,} a local constriction occurs in the case of ductile materials, in the region of which the fracture occurs. The largest relative change in cross-section occurring in this case is referred to as break-neck Z. This is a measure of the ductility of the material:

with the starting cross-sectional area S _{0 of} the unloaded test bar and the smallest cross-sectional area S _{u of} the broken bar, that is, the residual cross-sectional area at the constricted point.

The tensile strength is the stress calculated in the tensile test from the maximum tensile force achieved, based on the original cross section of the sample. As a symbol of tensile strength, for example, the name Rm is used. Dimension of tensile strength is force per area. Commonly used units are N / mm ² or MPa. Tensile strength is often used for the characterization of materials.

The uniform elongation A ₀ is the tensile test on the initial length L ₀ oriented plastic change in length L ₀ -L _pm in stress on the tensile test specimen with the maximum force F _m. This is usually achieved at the tensile strength Rm. The uniform elongation A _g indicates that the tensile specimen does not constrict to the maximum force but expands evenly. The yield strength R _e is a material characteristic value and designates the stress up to which a material exhibits no permanent plastic deformation with uniaxial and torque-free tensile stress. It is a yield point. When the yield strength is exceeded, the material no longer returns to its original shape after relieving, but a sample extension remains. The yield strength is usually determined by tensile testing. Components / components made of steel materials in the tensile strength range between 600 MPa and 1,200 MPa are becoming increasingly important. The steel banana (see Fig. 1) is characterized in that the product of tensile strength and elongation at break over many steel grades is approximately the same and for conventional low-cost stave with ferritic, pearlitic, bainitic or martensitic matrix at about 15,000 MPa *% lies. The product of tensile strength (Rm) measured In the quasi-static tensile test in MPa and elongation at break (A) in% can be used as a simple quality criterion for a steel, paying particular attention to the different criteria for measuring the elongation at break. Usually, the total elongation at break A5, consisting of a proportion equal expansion and a proportion of constriction strain for this comparative presentation is used. Increasing the ductility while maintaining the same strength allows on the one hand a higher energy absorption in case of overload (component safety), and on the other hand there is the potential for further cold-forming steps, so that more complex components can be manufactured.

A design goal for the production of new, high-strength steels is therefore often the increase of this product from Rm * A. Results of such efforts are, for example, TRIP steels and TWIP steels with a product of Rm * A of in some cases more than 50,000 However, for various reasons such as cost and difficulty in processing, the practical use of such steel grades is currently limited. In FIG. 1 MILD means conventional deep drawing grades, BH "bake hardening steel", ie higher strength steels with yield strength increase by the paint branding, IF "interstitial free steel", ie steel without interstitially dissolved alloying parts, HSLA "high strength low alloy steel", ie high strength low alloy steel , TRIP "transformation induced plasticity steel", ie steel with crystal lattice transformation induced ductility, TWIP "twinning induced plasticity steels" DP-CP dual phases / complex phases with soft ferrite, MS martensite phase steel, IS isotropic steel, IF-HS higher strength IF steel, CMn manganese carbon steel (standard structural steel).

Semi-finished products are the generic term for prefabricated raw material forms such as sheets, rods, tubes and coils. Semifinished products are by far the most widespread delivery method for metal materials in manufacturing technology. There are more than 1, 000 types of semi-finished products made of metal and plastic, each of which is standardized in terms of material and surface quality, shape and dimensions and tolerances. It is typical for semi-finished products that the first processing step consists of a blank in which the required section of material is separated by a suitable method (for example sawing). This material section is processed further to the actual finished part.

High geometric accuracy of semi-finished products and end products is achieved by a cold forming, for example cold rolling of strip material, cold drawing of tubes, cold heading of rod material, thread rolling, etc .. The cold forming also increases the strength of the semi-finished products and products. Significant cold working generally causes the drastic decrease in ductility, the product of tensile strength and elongation decreases dramatically.

For example, a cold strengthened steel with a strength of 1,000 MPa and a resulting elongation of 2% has only one product Rm * A of 2,000 MPa%.

The use of work hardening of cost-effective low-alloyed steel grades is of great importance for economical lightweight construction in various applications.

With the increase in strength, however, a significant decrease in the ductility is disadvantageously associated, so that a further plastic deformation in subsequent processes is not directly possible. In addition, a plastic deformability is often required for component safety, so depending on the application depending on the application, a more or less large power consumption is possible. For adjusting an improved ductility after cold working, the steel is usually subjected to a heat treatment. When annealed under a protective gas (e.g., nitrogen, argon) in the range of 600 to 700 ° C above the recrystallization temperature, the material recrystallizes, strain hardening is largely reduced, and high plastic deformability occurs. This process is commonly called normalizing.

Also, industrial practice is stress relief annealing below the recrystallization temperature. When annealing below the recrystallization temperature, so-called crystal recovery occurs in steels. Crystal recovery leads to the reduction of tension. Grain shape and grain size of the deformed structure are retained. With the degradation of internal tension is a moderate increase in ductility and a moderate drop in strength associated. The process window of such stress relief annealing is comparatively narrow, since the temperature usually has to be brought close to recrystallization in order to achieve a significant increase in ductility. This temperature is not only material dependent, but also dependent on the pre-deformation. Although stress-relieving can increase ductility, the product of Rm * A usually only reaches values below 10,000 MPa%. If high values of Rm * A with high strength are to be achieved, the narrow process window also poses a considerable risk for fluctuating product properties, which can lead to increased rejects. The heat treatment of the cold-solidified semi-finished products takes place for strip material in continuous annealing plants and stationary annealing annealing plants. Depending on the furnace load, only slow heating and cooling rates can be achieved. The crown annealing of strip material in the form of so-called coils, for example, requires up to several days because of the physically conditioned soaking times. Compensation of the material, ie transformation hardening and tempering, is generally not technically possible with these slow cycles. In addition, conversion hardening is disadvantageously associated with high temperatures and energy input, high costs and the risk of distortion of the semi-finished products. In the case of bell annealing, only normal annealing and stress relief annealing are used.

Thus, a high strength and high ductility at cold formed semi-finished products and products are difficult to achieve. In particular, with low-alloy, cold-formed steels, a strength of more than 750 MPa and an elongation at break A of more than 15% have hitherto hardly been reliably achieved in the cold deformation and stress relief annealing chain. Consequently, there is a technological gap in the strength range 700 MPa to 1 .200 MPa for ductile annealed cold strip with high ductility. This also applies to tubes and rod material, which are processed, for example, by cold drawing, cold heading, thread rolling, if compensation for cost reasons and technological reasons, eg occurrence of distortion, must be dispensed with.

Object of the invention

The object of the invention on this background is to provide a component of high strength and ductility that is technically easy to manufacture, and to provide a manufacturing method. The object was achieved by a component according to claim 1 and by a method having the features of the independent claim. Preferred embodiments are given in the dependent claims. Disclosure of the invention

To solve the problem is based on a low-alloy steel, which thus comprises a high proportion of iron. No alloying element of the low-alloyed steel exceeds an average content of 5 mass%. The proportion of iron in the steel alloy is in particular more than 90% by weight, preferably more than 96% by weight. The alloy includes copper as an alloying element. By cold forming a component is formed from the low alloy steel. The component is in particular a semi-finished product. Subsequently, the component is subjected to an annealing treatment below the recrystallization temperature. The applied temperature is in particular well below the recrystallization temperature, resulting in a contributes to technically simple production. In particular, the temperature is 100 ° C below the crystallization temperature.

The invention utilizes the strength-enhancing effect of precipitation hardening with copper. It is not known from the prior art that a marked increase in ductility occurs in cold strengthened steels of high strength parallel to the increase in strength. Thus, the invention utilizes precipitation hardening to simultaneously significantly increase the strength and ductility of the alloy and the semifinished product made therefrom. The invention enables a production-safe process sequence consisting of cold working and annealing below the recrystallization temperature, in particular for the production of semi-finished products and components, which preferably exhibit a high ductility in the strength range from 700 to 1.200 MPa. Elaborate production steps are avoided. A bell annealing or another annealing process with low temperature gradients is sufficient.

Precipitation hardening is known in many alloy systems, including steels. Thus, the known AFP steels (precipitation-hardening ferritic-pearlitic steel) achieve their high strength by precipitation hardening. This vanadium carbonitrides are excreted during cooling from the forge heat. Also higher strength fine grain steels, e.g. S700MC obtain their high strength generally by precipitation hardening over carbides, nitrides and carbonitrides of the refractory metals, especially titanium, niobium, vanadium, molybdenum and tungsten.

The precipitation hardening of steel by copper has also been known for more than 50 years (RC Glenn, E. Hornbogen, "A metallographic study of precipitation of copper from alpha iron", Trans. Met. Soc. AIME, Vol. 218, No. 6 For medium- and high-alloy steels, precipitation hardening with copper is known, and at temperatures between 350 and 550 ° C finely distributed Copper precipitates in the steel, which lead to a significant increase in strength (eg CN Hsiao, CS, Chiou, JR Yang, "Aging reactions in a 1- 7-4 PH stainless steel", Mater. Chem. Phys. Vol. 74, No. 2, Pp 134-142, 2002). Also known in the USA is the use of copper in relatively low alloy steels, eg SW Thompson, G. Krauss, "Copper precipitation during continuous cooling and isothermal aging of 710-type steels", metal , Mater. Trans. A, Vol. 27, No. 6, pp. 1573-1588, June 1996. However, these are generally additionally alloyed with nickel. Conventional are alloy contents of 1 -4 wt .-% copper to achieve precipitation hardening.

It is further known that further increases in strength can be achieved by simultaneous elimination of the classical carbonitrides, for example Tic and V (C, N).

Copper as an alloying element is often considered a pest in steel, since the undesirable red brittleness can occur. Red brittleness arises during the hot forming of the steel in the temperature range between 1 .000 and 1 .200 ° C. Red brittleness is due to the formation of molten copper by selective corrosion: at high hot working temperatures, the iron oxidizes / scales on the surface, while the nobler copper accumulates. High copper-containing edge zones then become molten. The occurring copper melt reaches the austenite grain boundaries in the steel, so that cracks and fractures form under the least load. Red brittleness is prevented in practice by alloying with nickel, which causes a change in the oxidation and thereby hinders the occurrence of selective corrosion. However, the proven alloying with nickel is disadvantageous because of the very high alloying costs. Nickel contents on the order of the usual copper contents are generally not accepted in the automotive industry for cost reasons. Preferably, the low alloy steel, which is believed to contain no nickel or only a very small proportion of nickel. The solution pursued in accordance with the invention is thus the use of precipitation hardening via alloying with copper, wherein the usual alloying with nickel is to be completely or at least largely dispensed with for reasons of cost.

In the manufacturing process chain of steel semi-finished products, forming at the critical red brittleness temperatures is the industrial practice. The substitutability of a new steel alloy in industrial production therefore requires measures to suppress the effect of red brittleness. The red brittleness is promoted by too long hold times when heated in inappropriate furnace atmospheres.

It is known that the phenomenon of red brittleness can also be avoided by the skillful procedure in the production process chain. For example, the oxygen partial pressure can be reduced by suitable furnace atmospheres when heated in the furnace, so that no selective corrosion occurs. However, it is desirable for practical application if the alloy according to the invention has a lower sensitivity to red brittleness.

Hot tensile tests on samples from different experimental melts were able to show that cost-effective alloying with boron according to the invention advantageously increased the hot ductility considerably. At a test temperature of 1, 000 ° C, the fracture waist Z as a measure of the ductility in the hot tensile test could be increased from 25% to 94%.

Further characterizations of the experimental alloys initially revealed the expected effect of an increase in strength of about 200 MPa per percent copper addition described and described in the literature. In the case of precipitation hardening after different degrees of cold deformation, a surprising, considerable increase in ductility was also observed far below the usual recrystallization temperatures. At low annealing temperatures of preferably below 420 ° C., a considerable increase in the elongation at break of flat specimens of the gauge length 50 mm A50> 15% could be ascertained in the trial alloys according to the invention at the same time as an increase in strength. In A50, the number 50 represents the gauge length. The increase in strength is dependent on the cold forming: low work hardened samples (15%) show a higher strength increase (15%) than high work hardened samples (> 60%) with only a slight increase of 2%. Thus, different degrees of strain hardening are partially compensated by the precipitation hardening with copper.

In addition, the alloys of the invention are characterized by a high cold workability of more than 80%. The strength and ductility can be varied at a high level above a yield strength of 750 MPa by varying the degree of deformation and heat treatment temperature. In this case, high products of strength Rm and elongation at break A50 of more than 15,000 MPa% are achieved. Even at annealing temperatures below 420 ° C Gleichmaßdehnungen A _g of more than 10% can be achieved.

The alloy according to the invention necessarily contains iron and copper and furthermore one or more of the constituents furthermore mentioned below. In the following, all percentages are based on wt .-% of the total alloy, unless otherwise stated.

Iron: The main constituent of the alloy is iron in an amount of preferably at least 96% by weight. A high iron content ensures Low costs related to the composition of the alloy and processing throughout the process chain. Higher alloy contents or lower iron contents lead in the classic steelworks, in which mass steels are produced cost-effectively, to long times for the alloy treatment in the ladle, so that a cost-effective production process is hindered. Copper: 0.5-2.0% by weight, preferably 0.8-1.6% by weight, particularly preferably 1.0-0.5% by weight. Copper improves cold workability at high base strengths. Copper is dissolved in the ferrite mixed crystal and leads to a solid solution hardening of about 40 MPa per% of dissolved copper. During the heat treatment in the temperature range of 250 ° C to 600 ° C, the copper leaves the alpha solid solution and forms fine precipitates. The precipitates provide a significantly higher contribution of about 200 MPa per% of precipitated copper to the strength than the previous solid solution hardening. The lattice of the alpha mixed crystal, which is braced by an upstream work hardening, is expanded by diffusing out the Cu atoms, so that the ductility increases significantly below the recrystallization temperature. Below 0.4% by weight of copper, the effect of the copper is comparatively low. Above 1, 5 wt .-% is limited for cost reasons, the use of

Carbon may be present in small proportions, preferably 0.04-0.12% by weight, particularly preferably 0.04-0.08% by weight. A low carbon content ensures very good formability and a very good weldability. In particular, the cold forming is therefore promoted by the carbon content. Cr-Si-Mn-Ni: By varying the contents of Cr, Si, Mn and Ni, the basic strength of the steel and the hardening behavior are influenced. The sum of Cr + Mn + Si + Ni is according to the invention preferably in the range of 0.5 to 2.5 wt .-%. In particular, the contents of silicon and manganese are as follows. wherein the total amount of Cr + Mn + Si + Ni is as defined above:

Silicon: 0-2% by weight. preferably 0.8-1.2% by weight. An appropriate Si content has a favorable influence on the ductility and solidification in the cold working and improves the scale resistance and therefore also has a positive influence on the reduction of the risk of red brittleness. Manganese: 0.3-2% by weight. preferably 0.3-0.6% by weight. A comparatively low Mn content has a favorable influence on the segregation behavior in continuous casting and improves the formability. A higher manganese content of 0.6 to 2% leads to a higher basic strength.

Nitrogen: preferably 0 to 0.01 wt .-%, particularly preferably 0.003 - 0.008 wt .-%. Nitrogen is regularly a common accompanying element.

Boron: preferably 0 to 0.01 wt .-%, particularly preferably 0.001 to 0.005 wt .-%. Boron is surface-active as a dissolved element in austenite. It improves hardenability in conventional low alloy alloys by retarding ferrite nucleation at the austenite grain boundaries. Here, the boron addition reduces the risk of red rot.

Aluminum: preferably 0 to 0.04 wt .-%. Aluminum is a common alloying element for deoxidation which is added especially at low levels of manganese and silicon. Ti-Nb-V-Mo-W: These refractory metals form carbides and nitrides which, as fine precipitates, can increase strength. A simultaneous increase in strength by excretion of refractory carbonitrides in addition to curing with Cu is possible. The sum of the mentioned elements should initially be alone Cost reasons are less than 0.3 wt .-%. In addition, the effectiveness of the refractory metals is linked to available carbon and / or nitrogen. Titanium: preferably 0 to 0, 1 wt .-%, particularly preferably 0.02 to 0.05 wt .-%. Titanium binds the undesirable nitrogen in the ratio of Content in% by weight at high temperatures> 1000 ° C. and prevents the formation of undesired boron nitrides. Above this content, Ti is available for precipitation hardening together with C at low temperatures in the range 300-600 ° C. Titanium carbides may contribute to further precipitation hardening in parallel to the copper precipitates. A disadvantage associated with higher Ti contents is the setting of the dissolved boron in the form of titanium borides, which form even at high temperatures.

The alloy of the invention may contain small amounts of other elements, for example in the form of the usual accompanying elements as impurities. These impurities are mostly unavoidable admixtures such as e.g. Sulfur and phosphorus, tin, antimony. The amount of impurities depends on the production routes in the steel mill and should generally be less than 0.03 wt .-% in total.

The alloy particularly preferably consists of (in% by weight, based on the total alloy, the sum of all constituents being 100% by weight)

Iron ≥ 96

Carbon 0.04 to 0.12

Copper 0.5 to 2.0

Manganese + silicon + chromium + nickel 0.5 to 2.5

Titanium 0 to 0.1 Boron 0 to 0.005

as well as usual unavoidable impurities. In the production of semi-finished products and components made of this alloy, a combination of cold working and annealing treatment below the recrystallization temperature is used.

The component according to the invention is preferably a semifinished product in the form of sheet metal, tube or rod, since in these semifinished products high accuracy and / or low wall thicknesses are required for efficient lightweight construction. The use of cold-formed material is advantageously associated with tight tolerances and good, scale-free surfaces.

From the semi-finished other components can be produced. Inventive other components can be made from the semifinished product flat material, wire and tube and combinations thereof. The necessary cold working either takes place already during the production of the semi-finished products, e.g. Cold strip, cold formed, e.g. drawn pipe and / or wire of the alloy, or only at the final deformation of soft semi-finished product. Particularly advantageously, the technology is suitable for components with variable wall thicknesses, e.g. so-called TRB "Tailor Rolled Blank", since differences in strength can be partially compensated by different degrees of deformation The wall thicknesses, sheet thicknesses or cross sections of the components can be varied within the component, for example by up to 60% relative to the initial thickness or initial strength, for example reduced It is preferred to vary or reduce by at least 30%.

Overall, a cold deformation in the form of a cross-sectional decrease of at least 10% up to 90% is possible based on the initial cross-section. Preferably, the cold deformation of semi-finished products from the alloy according to the invention by conventional cold-forming process. Examples include cold drawing, cold rolling of strip and / or profiles, calibration rolls, cold heading, thread rolling, deep drawing, cupping, flow-forming, rotary swaging. The cold forming according to the invention is preferably carried out at temperatures below 400 ° C, more preferably at room temperature. The dimensional change achieved by the cold forming is preferably at least 10% based on the initial dimension.

The subsequent annealing to increase the ductility and strength according to the invention is carried out at temperatures of preferably between 300 and 600 ° C, preferably 350 to 500 ° C for a total duration of preferably 30 minutes to 48 hours, so that neither an undesirable distortion nor a scaling of surfaces occurs. The duration of the annealing treatment is variable within wide ranges, since, for example, large masses in the form of coils with several tons of weight have a high thermal inertia. For such masses results from the lowered compared to the usual stress relief annealing maximum temperature shortening the process time by several hours. The effectiveness of the process was verified in process times of 1 h for thin-walled components and 36h for large coils.

The excellent surface quality of the components according to the invention also ensures good fatigue properties under cyclic loading. In addition, with the low annealing temperatures, a significantly reduced energy consumption is required over the recrystallization annealing or tempering required in the prior art which requires heating to 600 ° C to 950 ° C. Conventional alloys, such as fine grain grades S355, S420MC, show a significant decrease in strength and only a moderate increase in ductility during stress relief annealing after cold working. The product of strength R _m and elongation A50 is usually below 10,000 MPa% after annealing below the recrystallization temperature. Gleichmaßdehnungen of more than 10% are achieved only above the recrystallization temperature of eg 600 ° C. Therefore, in industrial practice, components with appropriate strength requirements have so far mostly been tempered by tempering and tempering with disadvantages in terms of energy input, surface quality and accuracy due to distortion.

The alloy of the invention is prepared in a conventional manner, e.g. via the blast furnace route, direct reduction steel works and electric steel works. The alloy composition is prepared in conventional ladle metallurgy, the chemical composition being determined by suitable methods. e.g. Optical emission spectroscopy (OES) is tested. Casting usually takes place in continuous casting for the relevant mass production.

The rolling of tape and rod material is done for. In conventional hot rolling mills, e.g. Hot strip mills. Particularly advantageous is the production in integrated casting-rolling plants, since cost advantages arise here by favorable energy balance. In addition, the direct use of the steel from the casting heat without separate intermediate heating has fewer risks in terms of a potential risk of red rot.

Then, according to the present invention, the alloy is further processed by cold forming and the above-mentioned annealing treatment to obtain the desired high ductility and high strength. The components or semi-finished products according to the invention preferably have a product of tensile strength and elongation at break of at least 12,000 MPa *% and a tensile strength Rm of at least 600 MPa.

The semifinished product or component according to the invention preferably has a tensile strength of at least 900 MPa and more preferably of at least 1000 MPa, a yield strength R _p 0.2 of at least 800 MPa, preferably at least 900 MPa and an elongation at break of at least 10%.

Elongation at break A, tensile strength R _m and yield strength Rp0.2 according to the invention z. B. determined using standardized quasi-static tensile tests.

The invention will be further explained below by application examples. Components according to the invention are obtained, in particular, by a degree of cold working of more than 15% (based on the initial cross section), with low stress annealing and precipitation hardening at low temperatures of between 350 and 500 ° C. at the same time.

The invention achieves improved energy efficiency in the process chain from steel to product, since annealing temperatures can be significantly reduced. With polyphase steels (DP, CP, TRIP), a comparatively high fluctuation range of the properties can be observed. The high variability of properties in multiphase steels means that in the design of products the worst case must be assumed in each case, ie it is designed with relatively poor properties. By the present invention, significantly more uniform properties can be achieved, since these are not adjusted via complex time-temperature guides Need to become. It also disadvantages insofar as are avoided by the present invention.

Application 1:

One possible application is the resource-efficient production of cost-efficient steel tubes. The necessary cold forming is carried out by one or more cold drawing and / or calibration rolls. Seamless tubes are preferably processed by cold drawing, while welded tubes are often profiled in one pass in a sizing mill. At the same time, the tubes are often not only rolled to size, but also special profiles are produced in cross-section, so that complex hollow profiles can arise.

It has been customary to bring the ductility of the cold-formed tubes and hollow sections to a tolerable level by stress relief annealing below the recrystallization temperature (BKS annealing). However, this generally achieves only low ductility at limited strengths, e.g. 700 MPa strength at less than 10% elongation at break, for example, when a S460 is work hardened and low-stress annealed.

The material and process combination according to the invention allows a strength of more than 900 MPa at an elongation at break of more than 15%, with low strengths at significantly higher elongation at break are also possible. The combination of materials and methods according to the invention thus simultaneously allows an increase in strength and ductility and a reduction in the annealing temperatures of previously generally greater than 600 ° C to well below 500 ° C, so that energy can be saved. In addition, the deformability is significantly better, so that higher degrees of deformation during drawing and / or calibration possible, as if, for example, common fine grain steels in the range S355 to S500MC be used.

Application 2:

One possible application of the alloy according to the invention is cold heading starting from wire or rod material. This is the usual method for the production of screws, fasteners, ball pins, etc., are placed on the high demands on strength and ductility. In the case of very high demands on strength, complex processes have hitherto been used to form conventional steel grades, such as 42CrMo4 or 41 Cr4, by drawing and cold forming with intermediate annealing to form a geometrically suitable component. Subsequently, then a compensation in the form of hardening and tempering with subsequent processing is required because the component surface must be reworked after the usual remuneration. It is known that bainitic cold heading grades have been used in recent years, which allow the setting of a high strength even without tempering treatment, eg 8MnCrB3 or 8MnSi7. Strengths of 800 MPa and slightly above are possible without a tempering treatment. These materials obtain their strength from the bainitic structure and a cold work hardening. In comparison to the material and process combination according to the invention a lower formability is present. The material and process combination according to the invention, due to its excellent cold workability, enables complete cold shaping even of complex geometries without intermediate annealing. In this case, larger transformations than when using the mentioned Kaltstauchgüten are possible. A work hardening on a yield strength of more than 1 .000 MPa is possible. The subsequent annealing process according to the invention in the temperature range of 300-500 ° C allows an increase in the elongation at break to more than 12%.

Application 3:

The production of thin sheets of steel - usually below about 2 mm to less than 0.1 mm - takes place as a cold strip. Cold rolled strip can also be produced in different, graded thicknesses as so-called TRB material. The different thicknesses allow improved lightweight construction through targeted use of materials. Lightweight construction with steel requires the highest possible strength with good ductility. Analogous to the applications 1 and 2, the use of the material and process combination according to the invention allows a considerable increase in the ductility and strength compared to the prior art.

Application 4:

The processing of sheets (and profiles) requires a high formability for complex geometries. The material and process combination according to the invention can also be used in the processing of metal sheets (and profiles), for example by deep-drawing, cupping and similar processes. Here, the semifinished product is used in a normalized / recrystallized state. The excellent formability makes it possible to produce complex geometries, eg via drawing technology and / or bending technology. This is followed by an annealing treatment which, although at 300-400 ° C., is above the otherwise usual bake-hardening temperature, but permits a comparatively high increase in strength. While an increase in strength between 40-90 MPa is possible via bake hardening, according to the invention the strength can be increased by more than 200 ΜΡα be increased. Thus, complex shaped components with a strength of more than 600 MPa can be produced, while common bake hardening steels in use are limited to below 400 MPa.

A component produced in a demanding manner differs in terms of its structure from the prior art and can therefore be identified, as will be explained below.

FIG. 2 shows a microstructure of a low-alloyed ferritic steel with small proportions of perlite in the normalized state. The perlite is recognizable as a black microstructure constituent. The microstructure corresponds to CMn steel in FIG. For low carbon steels, in the normalized state, small pearlitic islands are embedded in a ferritic matrix. HSLA steels also show a similar microstructure, but with micro-alloying and a special thermomechanical treatment, they have significantly smaller grains.

FIG. 3 illustrates how the microstructure of FIG. 2 is changed by cold forming. Shown is the microstructure of a cold-rolled steel according to FIG. 2 after a high cold deformation (thickness decrease from 8 mm to 2 mm without intermediate heating). Clearly visible are elongated grains due to the cold deformation corresponding to the direction of deformation. However, the ductility of such a structure is low, so that at high strengths usually an elongation at break A5 of less than 10% is present. A semifinished product and / or component according to the invention exhibits a corresponding microstructure according to FIG. 3, since it was annealed to low stress substantially below the recrystallization temperature. A stress-relieved structure

(Stress relief annealing (DIN EN 10052: 1993)) is characterized in that no significant change in the structure occurs: heat treatment consisting of heating and holding at a sufficiently high temperature and subsequent appropriate cooling to reduce internal stresses without significant change in the structure largely. With the reduction of residual stresses, the ductility increases comparatively slightly. Typically, temperatures between 550 and 650 ºC are required. In contrast, according to the invention, preferably temperatures between 350 ° C and 500 ° C are used to eliminate Cu particles. Accordingly, components according to the invention are distinguished by the copper particles, which are frequently described in the scientific literature, in the size between 1 and 20 nanometers.

FIG. 4 shows the microstructure of the cold-rolled steel from FIG. 3 after annealing above the recrystallization temperature. Significantly new globular grains and a finer expression of the cementite are recognizable. As a rule, the recrystallized microstructure is finer than the microstructures of FIGS. 2 and 3. As FIGS. 2 and 3 make clear, it can be ascertained by means of an investigation of the structure whether a component has been obtained by cold forming or not. As illustrated in FIGS. 3 and 4, a microstructural examination makes it possible to ascertain whether a component has been annealed above the recrystallization temperature or not. For the determination of the recrystallized microstructure, point and linear cross-section techniques are used in classical light microscopy. In case of doubt, an EBSD analysis (Electron Beam Backscatter Diffraction) can also show, for example, if recrystallization is present. In order to distinguish the recrystallized and non-recrystallized state, the scattering of the misorientation angle in a grain can be used here. If recrystallised and non-recrystallized fractions are present, they can be deposited, for example, via the Distribution misorientation scattering can be visualized. If this scattering is small, a recrystallized grain is present.

By cold forming followed by stress relief annealing high strength steels can be produced, which are shown in FIG. 5 compared to Figure 1 as SR (low-stress annealed) were inserted. It can be seen that, although similar strengths as in modern HSLA, DP, CP, TRIP steels are achieved, but a significantly lower ductility is present. This low ductility is not sufficient for many applications.

Steel according to the invention incl. Semi-finished products and components were compared to Figures 1 and 5 as SPH (stress relieved, precipitation hardened) in FIG. 6 inserted. Compared to the classic, cold-formed and stress-relieved SR grades, they offer higher strength and higher ductility. With regard to strength and ductility, a wide range can be reproduced by alloy variation, variation of the cold forming and variation of the annealing treatment. The product of strength Rm and elongation is regularly higher than SR steels and can reach the usual level of HSLA, DP, CP steels.

The determination of the ductility and / or the analysis of the Cu particles make it possible to determine whether an annealing treatment has been carried out in the claimed manner or not.

Overall, therefore, it can be determined with a component whether it has been produced by cold forming and subsequent annealing significantly below the recrystallization temperature and thus falls within the claimed range or not.

FIG. 7 illustrates the positive effect of boron and also titanium on the high-temperature ductility in Cu alloyed steels. Compared is a low alloy steel designated MT 12-05 with a low-alloyed steel, which is designated in FIG. 7 with MT12-06. Both steels comprised 0.06 wt% C, 1 wt% Si, 0.8 wt% Mn, and 1 wt% Cu. The steel MT12-06 additionally comprised 0.03% by weight of Ti and 0.003% by weight of B. The percent deformability is plotted until the material fails to withstand the temperature. Figure 7 shows that the steel MT12-06 can deform significantly more than steel MT12-05. Consequently, the high-temperature ductility of Cu-alloyed steels can be significantly improved by B and Ti, thus lowering the risk of red rot.

Claims

claims

1 . The low-alloy steel component comprises iron and, as an alloying element, copper obtained by cold-working the steel alloy and then annealing at a temperature below the recrystallization temperature of the steel alloy.

2. Component according to claim 1, characterized in that the annealing treatment has been carried out at a temperature which was at least 100 ° C below the recrystallization temperature of the steel alloy and / or not more than 420 ° C and / or at least 300 ° C, preferably was at least 350 ° C.

3. Component according to claim 1 with a microstructure, characterized by more than 80%. preferably 100% unrecrystallized grains after cold working, which can be detected, for example, by EBSD analysis.

4. Component according to one of the preceding claims, characterized by Cu particles in the average particle size between 1 and 50 nanometers.

5. Component according to one of the preceding claims, characterized in that the proportion of copper in the low-alloyed steel 0.5 to 2 wt .-%, preferably 0.8 to 1, 6, particularly preferably 1, 0 to 1, 5 Wt .-% is.

6. Component according to one of the preceding claims, characterized in that the steel alloy, from (in wt .-% based on the total alloy, wherein the sum of all components 100 wt .-% results) - Iron ≥ 96

- Carbon 0.04 to 0.12

- Copper 0.5 to 2.0

- Manganese + silicon + chromium + nickel 0.5 to 2.5

- Titanium 0 to 0, 1

Boron 0 to 0.005

- as well as usual unavoidable impurities

consists.

7. Component according to one of the preceding claims, wherein the proportion of silicon in the low alloy steel 0 to 2 wt .-%, preferably 0.8 to 1, 2 wt .-% is.

8. Component according to one of the preceding claims, wherein the proportion of manganese in the low-alloy steel 0.3 to 2 wt .-%, preferably 0.3 to 0.6 wt .-% betrögt.

9. component; according to any one of the preceding claims, wherein the proportion of chromium in the low alloy steel is 0 to 0.8% by weight, preferably 0 to 0.3% by weight.

10. The component according to one of the preceding claims, wherein the proportion of boron is 0.001 to 0.005 in the low alloy steel wt .-%.

11. The component according to one of the preceding claims, wherein the proportion of titanium in the low-alloy steel is 0.02 to 0.05 wt .-% and the titanium content of 3.2 times the amount in wt .-% nitrogen,

12. Component according to one of the preceding claims, wherein the proportion of refractory metals Ti, Nb, V. Mo. W in the low-alloy steel is at most 0.3 parts by weight.

13. The component according to one of the preceding claims, wherein the proportion of carbon in the low alloy steel is 0.04 to 0.08 wt .-%.

14. Component according to one of the preceding claims, wherein the component or semi-finished product has a product of tensile strength Rm and elongation at break A of more than 12,000 MPa *% and its tensile strength Rm is greater than 600 MPa.

15. Component according to one of the preceding claims, wherein the tensile strength Rm is at least 900 MPa, preferably at least 1 .000 MPa, the yield strength Rp0.2 at least 800 MPa, preferably at least 900 MPa, wherein the component is a product of tensile strength Rm and elongation at break A. of more than 12,000 MPa *%.

16. Component according to one of the preceding claims, wherein the component has been manufactured from flat material of a thickness of 0.6 to 6 mm.

17. A component or semifinished product according to one or more of claims 13 and 14, wherein the component or semifinished product has been produced from round material with a diameter of 3 to 30 mm or from tube material with an outer diameter of 4 to 60 mm.

18. Component according to one of the preceding claims, wherein the component wall thickness differences or differences in sheet thickness or cross-sectional differences of more than 10% within the component having respect to the maximum value.

19. A method for producing a component according to one of the preceding claims from a low-alloy steel, which comprises copper as the alloying element, comprising the steps

- Cold forming at temperatures below 400 ° C, preferably room temperature, by at least 10%

Dimensional change relative to the initial value,

- Annealing at 300 to 600 ° C, preferably at 350 to 500 ° C and below the recrystallization temperature of the steel for a total duration of 30 minutes to 48 h.