WO2020119981A1 - Steel product having a high energy absorption capacity under sudden stress, and use of such a steel product - Google Patents

Abstract

The invention relates to a steel product having a high energy absorption capacity under sudden stress, said steel product having the following alloy composition in wt%: 0.10 to less than 0.75 C, 0.10-4.00 Si, 0.50-4.00 Mn, 0.05-2.00 Cr, max. 0.025 N, max. 0.15 P, max. 0.05 S, remainder iron with impurities resulting from steel production, and the steel product having a microstructure which is lamellar. The minimum energy absorption capacity to be achieved of the steel product fulfils the following condition (equation 1): Emin = 450x D–2000 (1), where E is the energy absorption capacity in kilojoules (kJ), the numerical value 450 is in kilojoules per mm (kJ/mm), the numerical value 2000 is in kilojoules (kJ) and D is the thickness of the steel product in millimetres (mm).

Description

Steel product with high energy absorption capacity with sudden stress and use of such a steel product

The invention relates to a steel product with a high energy absorption capacity

abrupt stress, particularly in vehicle construction or when fired or blasted and the use of such a steel product. The term “armor” is also used as a synonym for such steel products. In the following, “steel products” are understood to mean in particular hot-rolled products, such as heavy plate with a thickness of approximately 3 mm to 250 mm and also hot and cold strip with a thickness of approximately 0.5 mm to 25 mm.

In general, corresponding steel products should have a high energy absorption capacity in the event of sudden stress, that is to say the impact energy should be as complete as possible

absorb. In the best case, for example, the projectile should get stuck in the armor during a bombardment, i.e. not penetrate through the armor. In addition, the plastic deformation of the armor by an incoming projectile should not lead to an excessive expansion of the steel product.

Steels and steel products made therefrom with a high energy absorption capacity in the event of sudden stress, in particular when subjected to fire or blasting, have long been known. For example, the utility model DE 7138758 U discloses bulletproof armor for motor vehicles, which consists of an outer, preferably surface-reinforced steel plate and a plastic layer arranged behind it.

The published patent application DE 10 2016 108 278 A1 discloses a multilayer

band-shaped composite material made of steel with an applied non-metal layer, which should be bulletproof. These known steel armor plates are very complex due to the additional non-metallic coatings required

Manufacturing and therefore expensive.

From the published patent application DE 10 2005 023 952 A1, security armor for protection against shelling is also known, which is enriched with carbon in the edge zone on the firing side with at least 0.5 mass% and has a minimum hardness of 55 HRC on the top surface. This armor has particular disadvantages due to the high carbon content on the shelling side, which significantly reduces the weldability. The invention has for its object a steel product with high

To provide energy absorption capacity in the case of sudden stress, which avoids the disadvantages of the known armouring, is less expensive to produce and, moreover, has good welding suitability. In addition, an advantageous use of such a steel product is to be specified.

The invention solves these problems with the features of claims 1 and 12. Advantageous refinements are the subject of dependent claims.

According to the invention, a steel product with high energy absorption capacity is used with sudden stress, with a minimum hardness of 52 HRC and one

Minimum toughness of 27J at -40 ° C provided that from the following

Alloy composition in% by weight consists of:

0.10 to less than 0.75 C.

0.10 - 4.00 Si

0.50 - 4.00 Mn

0.05 - 2.00 cr

Max. 0.025 N

Max. 0.15 p

Max. 0.05 S balance iron with melting-related impurities with optional addition of one or more elements of Al, Mo, Ni, Co, W, Ti, Nb, or V as well as Zr and rare earths (SEM)

and has a structure that is lamellar, the minimum energy absorption capacity Emin to be achieved of the steel product fulfilling the following requirement (equation 1):

Emin = 450 x D - 2000 (1) and where E is the energy absorption capacity in kilojoules (kJ), the numerical value 450 in kilojoules per mm (kJ / mm), the numerical value 2000 in kilojoules (kJ) and D the thickness of the steel product in Millimeters (mm) is specified.

In this context, the term “lamellar microstructure” means that the microstructure is strip-shaped in the thickness direction of the steel product. The structure preferably has at least two different structural layers with different ones

mechanical properties.

The disadvantages of the prior art are avoided with the steel product according to the invention. The steel composition can be easily welded by the alloy composition according to the invention and is inexpensive to produce. The findings on which the invention is based are based on investigations which have shown that, in the case of a lamellar structure in the thickness direction, the energy with sudden stress initially causes the steel to deform in the thickness direction of the steel, in the deformation base of which cracks then subsequently occur, which up to now migrate a boundary of the microstructure and from there continue to spread essentially along the structural boundaries perpendicular to the load. The crack caused by the impact energy thus introduced does not run through the sheet in the thickness direction, but is advantageously deflected in a direction essentially perpendicular to the load in the steel in accordance with the layer structure. In the event of a bombardment, it is advantageously achieved that the projectile gets stuck in the workpiece or bounces off and the energy is thus completely absorbed by the steel according to the invention.

According to the invention, the layered microstructure can consist, for example, of different microstructures depending on the thickness. The structure layers can be predominantly martensitic, austenitic, ferritic or bainitic. For example, related to the sheet or strip thickness in the

Edge areas are predominantly martensitic and within predominantly ferritic or bainitic microstructures, which have been adjusted, for example, by appropriate heat treatments. It is also possible through targeted

Influencing the solidification conditions in steel production to excrete a thin layer of low-melting phases in the steel, which form a preferred level for crack propagation under sudden stress. Here are the usual ones

Steel manufacturing processes applicable, such as continuous casting, thin slab and

Thin strip casting as well as block casting or the vertical or horizontal strip casting process.

It has been found that the energy absorption capacity of the steel product is sufficient if the condition Emin = 450 x D - 2000 is met. At a

Steel sheet with a thickness of 10 mm means that that is

The energy absorption capacity of the steel must be at least (450 kJ / mm x10 mm) -2000 kJ = 2500 kJ in order to meet the requirements.

According to the invention, a lamellar microstructure can also be produced, for example, by roll cladding, spray cladding or weld cladding, in which the applied plating has a different microstructure and / or alloy composition. Other processes for surface hardening include nitriding, boronizing,

Coating, laser hardening, laser cladding, shot peening or sandblasting or the like. The hardening of the surface layer is complex and causes high costs.

It is also advantageously possible for several to be cast by means of the horizontal strip casting

Pour layers on top of each other. This can be two or more

mutually different melts are placed on the casting belt, which solidify together with one another as well as with the casting belt to form a composite material.

The cast steels can have a different alloy composition and differ, for example, in their carbon contents, so that a gradient material with a lamellar microstructure is created, in which the grading of certain elements contained and thus the microstructure or the final mechanical, technological and / or associated with it functional property changes with increasing distance from the surface.

In addition, it is possible according to the invention that macroscopic chemical concentration gradients along the sheet or strip thickness are set by specific solidification conditions.

The hot, cold-rolled strip or heavy plate can also be subjected to an austenitizing heat treatment with subsequent hardening in order to produce the at least two different structural layers.

Furthermore, it is advantageously possible to produce different microstructures in the sheet by hot-rolling the sheet in the two-phase region alpha-gamma or by means of a gradient in the heat treatment of the rolled sheet.

The use of the term "to" in the definitions of the salary ranges, such as

for example 1.00 to 3.00% by weight, means that the basic values - in example 1.00 and 3.00 - are included.

Alloy elements are usually added to the steel in order to influence certain properties in a targeted manner. An alloy element in different steels can influence different properties. The effect and interaction generally depends heavily on the amount, the presence of others

Alloying elements and the state of solution in the material. The relationships are varied and complex. The effect of the alloy elements in the alloy according to the invention will be discussed in more detail below. Below are the described positive effects of the alloy elements used according to the invention.

Carbon: for reasons of sufficient strength of the material, the minimum content should not be less than 0.10% by weight. With regard to a sufficiently low martensite start temperature and thus the setting of a very fine one

Microstructure but still good weldability, the carbon content should not exceed 0.75% by weight. Carbon contents between 0.20 and 0.60% by weight have proven to be favorable, optimal properties being achieved if the carbon content is between 0.20 and 0.40% by weight.

Silicon Si: The addition of Si in higher contents promotes mixed crystal hardening, reduces the specific density and the

Elongation and toughness properties. Higher Si contents lead to

embrittlement of the material and affect the hot and cold rollability. Therefore, an Si content of 0.1 to 4.0% by weight, preferably 0.10 to 3.00% by weight, particularly preferably 0.25 to 2.5% by weight, is established.

Manganese: the addition of manganese in the range of 0.50 to 4.00% by weight results from a compromise depending on the respective requirements for the steel alloy

between strength that can be achieved through higher additions and one

sufficient toughness that can be achieved at lower levels. With a view to a very good or optimal combination of properties, the manganese content should

between 0.75 and 3.00% by weight or between 1.00 and 2.50% by weight.

Through the targeted addition of chromium of at least 0.05 to 2.00% by weight, the ferritic conversion can be specifically controlled for the setting of a finer structure. Chromium can also contribute to precipitation hardening.

Advantageous chromium contents are 0.10 to 1.75% by weight or between 0.25 and 1.50% by weight.

Micro alloying elements (eg Nb, Ti, V) can be added to achieve grain refinement, especially in combination with thermo-mechanical rollers. In the presence of carbon and nitrogen, these form precipitates that inhibit the movement of grain boundaries or sub-grain boundaries and / or dislocations. Nitrogen can be in the range from 0.0005% by weight, advantageously 0.0025% by weight to max. 0.025% by weight can be added to form fine precipitates (eg niobium or titanium carbonitrides). If necessary, aluminum can be alloyed to accelerate the ferritic or bainitic transformation or to shift the martensite start temperature.

In addition, a targeted combination of aluminum and silicon (, AI + Si> 4 x C ') can suppress cementite precipitation.

If necessary, for further strengthening e.g. Molybdenum (to

2.00% by weight), nickel (up to 5.00% by weight), cobalt (up to 2.00% by weight) or tungsten (up to 1.50% by weight) as alloy crystal hardeners. Alternatively or additionally, micro-alloy elements based on vanadium up to 0.20% by weight and / or titanium up to 0.10% by weight and / or niobium up to 0.50% by weight can be added. A total content of Ti, V, Nb of max. 0.75% by weight and a total content of Ni, Mo, Co, W, Zr should be max. 1, 0% by weight are observed.

To be able to take advantage of the effect of these alloying elements, one should be used

Minimum content of 0.01% by weight can be observed. Molybdenum can contribute to solid solution hardening. It can also have a positive effect on the

Temper resistance and hydrogen embrittlement.

Rare earths and reactive elements: the optional addition of rare earths and reactive elements such as Ce, Hf, La, Re, Sc and / or Y can be used to set a targeted lamella spacing and thus for further strength and / or

Toughness increases in total contents of up to 1% by weight.

FIG. 1 schematically shows the example of the crack propagation in the case of sudden stress on a steel product according to the invention with a lamellar structure. The example shows a heavy plate 1 with a thickness of 8 mm with the following steel composition in% by weight: 0.30 C, 1, 25 Si, 1, 94 Mn, 0.004 P, 0.001 S, 0.12 AI, 0.78 Cr , 0.1 1 Mo, 0.020 Nb, 0.013 N. The energy absorption capacity of the heavy plate was 2100 kJ.

The heavy plate 1 has a lamellar structure, in this case thin zones with different mechanical properties, which are represented by lines 2, 2 ″, 2 ″, 2 ″ ”. Lines 2, 2 ', 2 ", 2'" represent thin phases made of low-melting alloy components that characterize the lamellar structure. On the lower side of the sheet 1, a hemispherical impression 3 caused by a projectile bombardment can be seen in the sheet 1, at the lowest point in the sheet 1 cracks 4, 4 'were caused in the sheet 1, which initially continued until the next

Spread the structure boundary (line 2, 2 ') and then continue to walk essentially horizontally along these boundaries in the steel. The cracks 4, 4 'then move on until the in the steel of the heavy plate 1 is completely consumed. A continuous crack through the thickness of the sheet 1 is thus avoided.

FIG. 2 schematically shows the hardness curve along the sheet thickness from the example from FIG. 1. In the edge area of the sample there is a high hardness, which decreases with increasing distance from the edge and then increases again. This hardness curve is characteristic of a steel according to the invention with a lamellar structure, the respective

Microstructures have different mechanical properties.

Advantageous uses of a steel product according to the invention with a lamellar microstructure result, above all, in automobile construction for crash-relevant components or as safety steel for armouring in the event of fire or fire. Such a steel product can also advantageously be used as an enclosure for highly dynamic units, e.g. Engines or aircraft engines or for explosion protection. The one too

Use in space travel to protect against micrometeorites is conceivable.

Claims

Claims

1. Steel product with high energy absorption capacity with sudden stress, with a minimum hardness of 52 HRC and a minimum toughness of 27J at -40 ° C

provided, which consists of the following alloy composition in% by weight:

0.10 to less than 0.75 C.

0.10 - 4.00 Si

0.50 - 4.00 Mn

0.05 - 2.00 cr

Max. 0.025 N

Max. 0.15 p

Max. 0.05 S balance iron with melting-related impurities with optional addition of one or more elements of Al, Mo, Ni, Co, W, Ti, Nb, or V as well as Zr and rare earths (SEM)

and has a structure which is lamellar, the minimum energy absorption capacity of the steel product to be achieved fulfills the following requirement (equation 1):

Emin = 450 x D - 2000 (1) and where E is the energy absorption capacity in kilojoules (kJ), the numerical value 450 in kilojoules per mm (kJ / mm), the numerical value 2000 in kilojoules (kJ) and D the thickness of the steel product in millimeters (mm) is specified.

2. Steel product according to claim 1, characterized by the following contents in% by weight: 0.05 - 2.00 AI

0.01 - 2.00 mo

0.01 - 5.00 Ni

0.01 - 2.00 Co

0.01-1.50 W

up to 0.10 Ti

up to 0.50 Nb

up to 0.20 V.

with a maximum total content of Ti, V, Nb of 0.75% by weight and a maximum total content of Ni, Mo, Co, W, Zr of 1.0% by weight and REM of max. 1.0% by weight.

3. Steel product according to claim 1 and 2, characterized by the following contents in

% By weight: 0.20 to less than 0.60 C, advantageously 0.20 to less than 0.40 C.

4. Steel product according to at least one of claims 1 to 3, characterized by the following contents in% by weight: AI + Si> 4 x C

5. Steel product according to at least one of claims 4 to 4, characterized by the following contents in% by weight: 0.10-3.00 Si, advantageously 0.25-2.5 Si

6. Steel product according to at least one of claims 1 to 5, characterized by the following contents in% by weight: 0.75-3.00 Mn, advantageously 1.0-2.5 Mn.

7. Steel product according to at least one of claims 1 to 6, characterized by the following contents in% by weight: 0.10-1.75 Cr, advantageously 0.25-1.50 Cr.

8. Steel product according to at least one of claims 1 to 7, characterized by the following contents in% by weight: min. 0.0005, advantageous min. 0.0025 N.

9. Steel product according to at least one of claims 1 to 8 for the production of

Heavy plate with a thickness of 3 mm to 250 mm or hot and cold strip with a thickness of 0.5 mm to 25 mm.

10. Steel product according to at least one of claims 1 to 9, characterized in that the lamellar structure consists of at least two layers with different structures.

1 1. Steel product according to claim 10, characterized in that the structural layers are predominantly martensitic, austenitic, ferritic or bainitic.

12. Steel product according to at least one of claims 10 and 11, characterized

characterized in that one of the at least two structural layers consist of low-melting phases of the steel.

13. Steel product according to at least one of claims 10 to 12, characterized in that one of the at least two structural layers by rolling, explosive or

Weld plating has been created.

14. Steel product according to at least one of claims 10 to 12, in which the at least two structural layers have been produced by means of horizontal strip casting by pouring melts with different alloy compositions onto one another.

15. Steel product according to at least one of claims 10 to 12, characterized in that the hot, cold strip or heavy plate was hot-rolled in the two-phase region of the structure in order to produce the at least two different structural layers.

16. Steel product according to at least one of claims 10 to 12, characterized in that the hot, cold strip or heavy plate has been subjected to an austenitizing heat treatment with subsequent hardening to produce the at least two different structural layers.

17. Steel product according to at least one of claims 10 to 12, characterized in that for producing the at least two different structural layers that the hot, cold strip or heavy plate of an outer layer hardening by means of nitriding, boronizing, coating, laser hardening, laser cladding, shot peening or sandblasting has undergone.

18. Use of a steel product according to at least one of claims 1 to 17 in automotive engineering for crash-relevant components, as safety steel for armor

Shelling or blasting, as housing of highly dynamic units such as engines or aircraft engines, as explosion protection or in the field of space travel as protection against meteorites.