DE102020212926A1 - Process for forming a semi-finished product and device for carrying out the process - Google Patents

Abstract

In the method for forming a semi-finished product made from a low-alloy steel containing at least 0.2% by mass of carbon and at least 0.5% by mass of silicon, the semi-finished product that has at least its austenitization temperature is used in a forming tool and, while maintaining a Roughly formed at a cooling rate of between at least 30 K/s and a maximum of 100 K/s and an increased strain rate of between 1/s and 100 1/s until the martensite start temperature has been undershot. After reaching a temperature of the semi-finished product that is lower than the martensite start temperature, the forming is continued with a strain rate of less than 0.1 1/s and the semi-finished product is slowly shaped close to the final shape and the cooling rate is reduced to a value of less than 10 K/s, see above that between the martensite start and finish temperature, a diffusion-controlled homogeneous distribution of the carbon in the volume of the semi-finished product is achieved and the forming process is terminated when the martensite finish temperature is fallen below.

Description

The invention relates to a method for forming a semi-finished product and a device for carrying out the method. The semi-finished product consists of a low-alloy steel containing at least 0.2% by mass of carbon and at least 0.5% by mass of silicon. In addition to these, other alloying elements with a total mass fraction of less than 5.0% by mass should be included. However, silicon should be contained with a maximum of 2.5% by mass.

Low-alloy steels occupy a special position in the area of tension between effective lightweight construction using high-strength materials and cost-efficient, mass-produced production. Due to the small proportion or even the absence of cost-intensive alloying elements such as nickel, manganese, cobalt and boron, these steels are of great interest. With the help of intelligent heat treatment strategies, such as tempering, tailor-made and application-relevant strength and forming properties can be set. In the process, multi-phase structures made of, for example, martensite, bainite and ferrite/pearlite are also frequently produced in order to achieve the desired mechanical properties. However, there have so far been narrow limits with regard to the formability of these materials, especially in the highest-strength states with martensitic structures and strengths above 1500 MPa. Typically, low-alloy steels tempered in this way have elongations at break of only a few percent. The brittle failure behavior represents an essential limitation for both the use and the further processing of such steels. In the past 15 years or so, a heat treatment strategy has been researched that allows the production of ultra-high-strength, low-alloy steels with comparatively very high formability. With the help of the "Quenching and Partitioning"(Q&P) heat treatment strategy, low-alloy tempered steels are optimized by creating microstructures that contain a mixture of martensite and retained austenite in such a way that extraordinary combinations of properties are set. In principle, Q&P steels can be dispensed with cost-intensive alloying elements, only carbon and a sufficient content of silicon (approx. 1 - 2.5% by mass) are required for the realization of this heat treatment strategy. Silicon effectively prevents the formation of iron carbides so that the carbon present is available to stabilize the retained austenite. Q&P processing typically starts with austenitizing followed by quenching below the martensite start temperature of the steel under study. The quenching temperature (about 200 °C and thus above the martensite finish temperature) has a direct effect on the proportion of retained austenite. The subsequent heat treatment, similar to classic tempering, includes the diffusion-controlled distribution (partitioning) of the carbon from supersaturated martensite to retained austenite, which leads to its (partial) stabilization. The microstructures that can be custom-made in this way, consisting of hard martensite and ductile, stabilized retained austenite, are the basis for the unconventional combination of properties with extreme strength (R _m ≥ 2000 MPa) and high ductility (A ≥ 10%). Martensite formation is possible in the temperature range between the martensite start and martensite finish temperatures.

Below the martensite start temperature (M _s ), partitioning (250 °C) can be carried out, which leads to stabilization of the retained austenite. Irrespective of this, it has been shown that the formability of a Q&P heat-treated steel can be increased many times over from a moderately increased forming temperature (200 °C to 250 °C) in combination with a low forming rate (strain rate < 0.1 1/s), so that Elongations at break of almost 25% can be achieved. It is noteworthy that this increase in formability can be achieved by a low and almost constant hardening rate without any significant loss of strength. This mechanical behavior can be explained microstructurally by a complex interplay of deformation mechanisms, some of which can be thermally activated, within the different structural components (martensite and retained austenite).

In particular, the high, constriction-free formability at moderately elevated forming temperatures represents enormous potential for the economical manufacture of complex components made of ultra-high-strength steels. In addition to the excellent mechanical properties of the Q&P steels, the high attractiveness is also due to the fact that neither the required alloying elements for the production of these Steel alloys nor the necessary heat treatment strategy would generate increased production costs on an industrial scale, since the handling of the Q&P heat treatment process is very similar to the conventional heat treatment of quenching and tempering.

However, the problem that needs to be solved for the production technology is the need to realize very different cooling rates during the process. The economic integration of the partitioning of the material into the process chain is also very challenging. There are already approaches for conventional press hardening of sheet metal being pursued to address these issues. However, if hollow profiles such as pipes or other hollow bodies are to be formed according to the Q&P route, there is currently no way to reliably implement quenching and partitioning in one tool. A slow reshaping during the partitioning, in order to exploit the effects of the significantly increased formability, cannot currently be carried out either.

The present invention should start here and enable the realization of different Q&P routes (different cooling rates, integrated partitioning and forming with variable strain rates) within a forming tool, in particular an active media-based forming tool for hydroforming (IHU), in order to thus produce tubes and hollow profiles with the highest strengths, to be able to produce locally, property-optimized and economically.

Various steels (preferably manganese-boron steels; e.g. 22MnB5) can currently only be press-hardened within a tool, ie the steels are austenitized in a furnace (usually T > 900 °C), then in the tool inserted and quenched to below the M _f temperature during the forming process. If an additional partitioning for the Q&P route is to be carried out, then the already formed workpiece must be removed from the tool above the M _f temperature (approx. 200 °C) and placed directly in a furnace for a defined temperature. However, the thermal input leads to distortion, which consequently has a very negative effect on the component quality, especially if locally different degrees of deformation result from the deformation.

It is therefore the object of the invention to specify ways in which true-to-form forming of semi-finished products made of low-alloy steels is possible and the formed workpieces obtained have increased strength despite the lack of cost-intensive alloying elements, whereby this should be associated with low effort for carrying out the forming.

According to the invention, this object is achieved with a method having the features of claim 1. Claim 8 relates to a device for carrying out the method. Advantageous embodiments and developments can be implemented with features identified in the dependent claims.

In the method, the procedure is such that the semi-finished product, which has at least its austenitization temperature, is placed in an at least two-part forming tool and while maintaining a cooling rate of between at least 30 K/s and a maximum of 100 K/s and an increased strain rate of between 1 1/s and 100 1/s s is roughly reshaped. By the time the martensite start temperature (Ms) is reached, a deformation should be achieved that corresponds to at least 80% of the total deformation to be carried out on the workpiece.

Once a semi-finished product temperature has been reached that is at most 20%, at least 10% lower than the martensite start temperature, the cooling rate and strain rate in the semi-finished product should change. The forming is continued with a strain rate of less than 0.1 1/s (responsible for an additionally increased formability) and the semi-finished product is slowly formed close to the final shape. The cooling rate must be reduced to a value of less than 10 K/s so that there is sufficient time between the martensite start and finish temperatures for a diffusion-controlled, homogeneous distribution of the carbon in the volume of the semi-finished product.

The forming process ends when the temperature falls below the martensite finish. A formed workpiece obtained from the semi-finished product is removed from the tool after it has reached a temperature that is lower than the martensite finish temperature (M _F ) of the material.

The martensite start temperature is the temperature at which martensite formation begins during cooling. It is greater than the martensite finish temperature at which martensite formation stops after further cooling.

Forming and temperature treatment are therefore carried out within one forming tool. The contour of the workpiece achieved after forming can also be retained during the temperature treatment, during which essentially only the diffusion compensation of carbon in the material volume of the workpiece that has already been formed takes place, since it is still in the forming tool and cannot be distorted.

The increased strain rate that should be maintained above the martensite start temperature must be significantly higher than the strain rate that should be maintained during martensite formation.

The respective cooling rate can be changed in particular by varying the surface pressure between the surface of the semi-finished product and the surface of the tool. This is also possible alone or in addition to this by alternating the thermal conductivity of the forming tool from isotropic to anisotropic.

The surface pressure can be influenced by locally specific compressive force effects between the touching surfaces of the semi-finished product and the forming tool.

Switching from anisotropic to isotropic thermal conductivity on the tool can be achieved, for example, with so-called switchable coatings on the tool halves. In this case, the orientation of the crystal lattice can be changed in a defined manner by applying an electrical voltage to the layer. This also leads to direction-dependent thermal properties (thermal conductivity) of the coating. In this way, the local cooling rates on the semi-finished product can be influenced in a targeted manner by different levels of heat conduction in the forming tool. At the beginning of the process, the crystal lattice of the layer is aligned in such a way that very good heat conduction can take place between the forming tool and the semi-finished product. This leads to the desired high cooling rate (between 30 K/s - 100 K/s) of the semi-finished product. When the martensite start temperature is exceeded, the applied electrical voltage changes the crystal structure of the coating in such a way that heat conduction is significantly poorer (less than 10 W/mK) between the forming tool and the semi-finished product. This leads to the significantly lower cooling rates of less than 10 K/s, which are necessary for the partitioning of the material between the martensite start and finish temperatures.

When forming semi-finished products designed as a hollow profile or hollow body, the pressure of the compressed medium can be changed in a pulsed manner by changing the pressure increase inside the respective hollow profile or hollow body in order to actively influence the strain rate and the cooling rate. You can choose the pulsing with different amplitudes. Similarly, when sheet metal is being formed, for example, the compressive forces acting on the surface of the semi-finished product can be alternately increased and decreased again several times. If the surface pressure is reduced, a previously deformed area of the respective semi-finished product can relax as a result of elastic recovery. Subsequent to this, if the surface pressure increases, the forming is carried out further and the cooling rate can be increased again.

It is therefore possible to change the pressure of the compressed medium and the pulse duration of individual pressure pulses and to adapt them to the respective required forming requirements and cooling rates over time, taking into account the current temperature of the semi-finished material.

A gas such as nitrogen or argon, but also a liquid, can be used as the medium to be compressed.

In the temperature range between martensite start and martensite finish temperature, a strain rate of between 10 ^-3 1/s and 0.1 1/s should be maintained during forming.

The forming tool can be cooled with an integrated cooling system. The cooling system can advantageously be designed in such a way that areas of the tool with which forming or greater forming than in other areas of the semi-finished product are to be achieved are cooled more intensely. This can be achieved, for example, with cooling channels through which a cooling medium flows. A larger volume flow of cooling medium can be conducted through these cooling channels than in areas in which little or no deformation is to be achieved. Several smaller cooling channels can also be present there.

A device designed to carry out the method can have a device for defined influencing of the surface pressure between the surface of the semi-finished product to be formed and the tool surface designed for shaping during the forming of the semi-finished product and/or for actively influencing the direction-dependent isotropic or anisotropic thermal conductivity to be present.

There is also the possibility that surface areas of the tool with which no or only little shaping is to be carried out are provided with a thermally insulating coating. This can be a ceramic or glass-ceramic coating, for example.

With the invention discussed here, it is possible to carry out the complete Q&P heat treatment route with different cooling rates and strain rates in one stage in a forming tool while performing hydroforming or forming a sheet as a semi-finished product, so that workpieces with the highest strengths (R _m >> 1500 MPa) and Elongation at break (A > 10%), e.g. B. for crash-relevant applications with very high necessary energy consumption for the component, can be manufactured economically. In addition, a further process step can be implemented with a specially modified tool, which achieves additional formability of the material and thus makes higher degrees of forming of the material possible within the Q&P route.

With the invention, with appropriately trained and temperature-controlled forming tools by means of a controllable local heat exchange, which consequently brings about different cooling and stretching rates in the material, by varying the internal pressure, the active medium, acting compressive forces and other parameters, workpieces made of low-alloy steel with improved properties can be obtained. Compared to other established concepts, a forming tool should not be isothermal, but should be temperature-controlled. In particular, pipes, hollow bodies or hollow profiles can be the focus of the forming achieved with the invention as workpieces, and this can also be transferred to forming tools for sheet metal production.

Pressure-controlled heat transfer resistances in the semi-finished product can be used for locally different and variable cooling rates, such as high cooling rates with high surface pressure, if high internal pressure during hydroforming or compressive forces act on the forming tool.

Smaller cooling rates can be achieved by reducing the internal pressure or smaller compressive forces acting on the surface of the semi-finished product and the associated lower surface pressure or the associated springback (relaxation) due to the elasticity of the material.

It is also possible to control the surface pressure and the cooling rate by temporarily acting negative pressure and thus reduce the cooling rate.

As already mentioned, the cooling rate can also be influenced via "switchable heat conduction" by means of a tool coating. For this purpose, new types of tool steel and coatings can be used on a forming tool, which enable an increase or reduction in heat transfer or heat conduction as a function of direction (longitudinal, transverse), so that different areas of a forming tool with different isotropic or anisotropic heat conduction can be obtained.

Suitable sensors can be provided for controlled forming conditions (pressure, temperature, strain rate, eddy current testing for material conversion) in order to specifically monitor, control and, if necessary, regulate the properties in the material or a possible property grading, with which in particular the temperature profile over time at to be formed or formed semi-finished product and the currently achieved degree of deformation or the currently achieved deformation can be detected.

With the planned modifications within the tool and the process management, it is possible to implement the Q&P heat treatment for steels intended for this purpose (silicon content > 0.5% by mass) for semi-finished products. The aim is to achieve rapid cooling (>30 K/s) from a temperature that is lower than the austenitizing temperature to a temperature that is slightly lower than the martensite start temperature. A significantly lower cooling rate (as low as possible; at least < 10 K/s) must then be set (with the modifications mentioned) so that the semi-finished product in the forming tool, which is still closed, is under pressure and surface pressure (therefore only minimal to no component distortion). maximum possible time (the target here is a time of 30 s to 180 s) between the martensite start and the martensite finish temperature in the tool. If the temperature falls below the martensite finish, the so-called press partitioning and consequently also the Q&P heat treatment are finished and the formed workpiece can be removed.

For the additionally usable increased formability, the semi-finished product is quenched below the M _s temperature with the specially modified forming tool and then at very low strain rates (10 ^-3 to 0.1 1/s) and a significantly reduced cooling rate (as low as possible; < 10 K/s) further formed before the M _f temperature is undershot. The significantly increased formability during partitioning can be used, for example, for significantly better forming of secondary form elements on the workpiece and for calibrating tight radii.

Realizing the various Q&P process routes (press partitioning; press partitioning and slow forming during partitioning) within a forming tool with locally different cooling rates leads to completely new workpiece properties (high local degrees of forming, design, "tailored properties") with extraordinary property profiles (extreme strength). high ductility).

The invention makes it possible for the first time to implement the Q&P process route within a forming tool and thus to obtain high-strength workpieces with very high ductility. In this case, locally defined different cooling rates and consequently application-optimized, locally defined property profiles can be generated by the planned modifications to the forming tool in the workpiece formed according to the invention. Due to the targeted and slow forming between M _s and M _f temperatures, very high degrees of forming can also be achieved for the forming of further Secondary form elements are realized. There is no separate partitioning in an oven. In addition, with the partitioning integrated here, the workpiece remains surrounded by the forming tool and supported by the internal pressure or pressure forces of the forming tool, so unwanted and uneven distortion can be reduced to a minimum and this can be determined in advance and kept in the tool engraving, so that a very high component quality/precision is achieved.

The technical field of application for the technology of the single-stage Q&P heat treatment within a tool is very extensive. This is due to the fact that, due to the specifically adjustable cooling rates in the forming tool, each workpiece can be formed with exceptional and locally optimized property profiles. The extreme strength combined with very high ductility of the workpieces predestines them for any crash-relevant application in the automotive industry due to their very high energy absorption. With a single-stage forming tool for the complete Q&P route, the workpieces can also be manufactured with very short process times and with very good dimensional accuracy due to the permanently applied surface pressure. Machines that are already established for large series can also be adapted and expanded for the Q&P route. It is expected that a new workpiece class of Q&P steels (highly complex geometry, ultra-high strength and ductile) can be established and manufactured very cost-effectively. These advantages also open up a wide circle of users. This begins with the automobile manufacturers themselves and continues through the various system suppliers.

Claims (9)

Process for forming a semi-finished product made from a low-alloy steel containing at least 0.2% by mass of carbon and at least 0.5% by mass of silicon, in which the semi-finished product, which has at least its austenitization temperature, is inserted into an at least two-part forming tool and while maintaining a cooling rate of between at least 30 K/s and a maximum of 100 K/s and an increased strain rate of between 1 1/s and 100 1/s, coarse forming is carried out until the temperature has fallen below the martensite start temperature, and after reaching a temperature of the semi-finished product that is lower than the martensite start temperature, the forming is continued with a strain rate of less than 0.1 1/s and the semi-finished product is slowly shaped close to the final shape and the cooling rate is reduced to a value of less than 10 K/s, see above that between the martensite start and finish temperatures, a diffusion-controlled, homogeneous distribution of the carbon in the volume of the semi-finished product is achieved and the forming process ends when the temperature falls below the martensite finish temperature and a formed workpiece obtained from the semi-finished product is removed from the tool after a temperature that is lower than the martensite finish temperature of the material has been reached. procedure after claim 1 , characterized in that the cooling rate is changed by varying the surface pressure between the surface of the semi-finished product and the surface of the tool and/or an alternating adjustment from isotropic to anisotropic thermal conductivity of the forming tool is carried out. Method according to one of the preceding claims, characterized in that the cooling rate is changed exclusively in regions of the semi-finished product which are formed with the forming tool. Method according to one of the preceding claims, characterized in that when semi-finished products designed as a hollow profile or hollow body are formed by increasing the pressure inside the respective hollow profile or hollow body, the pressure of the compressed medium is changed in a pulsed manner, or compressive forces acting on the surface of the semi-finished product, which with applied to the forming tool, can be increased and decreased again several times in order to actively influence the strain rate and the cooling rate. Method according to the preceding claim, characterized in that the pressure of the compressed medium and the pulse duration of individual pressure pulses are changed. Method according to one of the preceding claims, characterized in that a strain rate of between 10 ^-3 1/s and 0.1 1/s is maintained during the forming in the temperature range between the martensite start and martensite finish temperatures. Method according to one of the preceding claims, characterized in that the forming tool is cooled with an integrated cooling system. Device for carrying out the method according to one of the preceding claims, characterized in that a device for the defined influencing of the surface pressure between the surface to be formed of the half tool and the forming tool surface designed for shaping during the forming of the semi-finished product and/or for actively influencing the direction-dependent thermal conductivity. Device according to the preceding claim, characterized in that surface areas of the forming tool with which no or only little forming is carried out are provided with a thermally insulating coating.