RU2809295C1 - Cold-rolled and double annealed steel sheet - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates namely to high-strength steel sheets with good weldability characteristics. Cold-rolled and double-annealed steel sheet made of steel having the following composition, wt.%: C 0.03 – 0.18, Mn 6.0 – 11.0, 0.2 ≤Al < 3, Mo 0.05 – 0.5, B 0.0005 – 0.005, S ≤ 0.010, P ≤ 0.020, N≤ 0.008, and optionally including one or more of the following: Si ≤ 1.20, Nb ≤ 0.050, Ti ≤ 0.050, Cr ≤ 0.5, V ≤ 0.2, iron and inevitable impurities formed during smelting - the rest. The sheet has a microstructure containing, in surface fractions: from 0 to 45% ferrite, from 20 to 50% retained austenite, from 5 to 80% annealed martensite, from 0 to 5% fresh martensite, carbide density below 4×10⁶/mm². In this case, the ratio ([C]_A ² x [Mn]_A) / (C% ² x Mn%) is satisfied, ranging from 4.5 to 11.0, where [C]_A and [Mn]_A are the carbon content and manganese in austenite, expressed in mass percent, C% and Mn% - nominal values of the C and Mn content in steel, wt.%. A weld of resistance spot welding of two steel parts made from cold-rolled and double-annealed steel sheet of the specified composition is characterized by the value α, which is at least 30 daN/mm², whereα - ratio of tensile strength, which is the force applied to destroy the weld point obtained by welding two parts, to the product of the diameter of the weld point and the thickness of the base of the seam.

EFFECT: sheets have high yield strength and tensile strength, and are also easy to form.

11 cl, 6 tbl, 3 ex

Description

The present invention relates to a high-strength steel sheet having good weldability characteristics and a method for producing such a steel sheet.

For the production of various products, such as parts of structural elements and body panels of automobile vehicles, it is known to use sheets made of DP (two-phase) steels or TRIP (transformation ductility) steels.

One of the major challenges of the automotive industry is to reduce the weight of vehicles to improve fuel efficiency, without neglecting safety requirements and in the light of protecting the global environment. In order to meet these requirements, the steel industry is constantly developing new high-strength steels in order to have sheets with increased yield strength and tensile strength, as well as good ductility and formability.

The essence of one of the developments carried out to improve mechanical properties is to increase the manganese content in steels. The presence of manganese helps to increase the ductility of steels due to the stabilization of austenite. However, these steels exhibit deterioration in properties due to brittleness. To overcome the mentioned problem, elements such as boron are added. These chemical compositions with the addition of boron are very viscous at the hot rolling stage, and the hot strip is too hard for further processing. The most effective way to soften this hot strip is periodic annealing, but this results in a loss of viscosity.

In addition to the mentioned mechanical property requirements, such steel sheets must show good resistance to liquid metal embrittlement (LME). Steel sheets coated with zinc or zinc alloy are very effective in terms of corrosion resistance and hence are widely used in the automobile industry. However, in practice, it has been discovered that arc or electric resistance welding of certain steels can cause specific cracks due to a phenomenon called liquid metal embrittlement (“LME”) or liquid metal induced cracking (“LMAC”). This phenomenon is characterized by the penetration of liquid Zn along the grain boundaries of the underlying steel base under the influence of applied stresses or internal stresses resulting from rigid attachment, thermal expansion or phase transformations. The addition of elements like carbon or silicon is known to have a detrimental effect on LME resistance.

In the automotive industry, this resistance is typically determined by introducing an upper limit value called the LME propensity score, calculated using the following equation:

LME propensity score = C% + Si%/4,

where %C and %Si denote, respectively, the mass percentages of carbon and silicon in the steel.

Publication WO2020011638 concerns a process for producing cold-rolled steel with medium to intermediate manganese content (Mn 3.5 to 12%) and reduced carbon content. Two technological routes are described. The first route involves a single intercritical annealing of a cold-rolled steel sheet. The second route involves double annealing the cold rolled steel sheet, with the first route being fully austenitic and the second route being intercritical. By selecting the annealing temperature, an optimal ratio between tensile strength and elongation is achieved. By lowering the annealing temperature, enrichment in austenite is achieved, which implies the presence of a high value of fracture stress along the thickness. However, the small amount of carbon and manganese used in the invention limits the tensile strength of the steel sheet to values not exceeding 980 MPa.

In view of the above, it is an object of the present invention to solve the above problem and to obtain a steel sheet having a combination of very good mechanical properties including tensile strength TS equal to 900 MPa or higher, uniform elongation UE equal to 11% or higher, yield strength equal to 700 MPa or higher, and satisfying the condition [(YS-200) x UE + (TS-300) x TE]/(C% x Mn%) higher than 29,000, wherein TE represents the total elongation of the sheet, expressed in %, strength tensile strength TS is expressed in MPa, yield strength YS is expressed in MPa, uniform elongation UE is expressed in %, C% and Mn% represent nominal wt. % C and Mn in steel.

Preferably, the steel sheet has a total elongation TE of 15.0% or more.

Preferably, the steel sheet according to the invention has an LME susceptibility index of less than 0.36.

Preferably, the steel sheet according to the invention has a carbon equivalent Ceq of less than 0.4%, the carbon equivalent being determined as follows:

Ceq = C%+Si%/55+Cr%/20+Mn%/19-Al%/18+2.2P%-3.24B%-0.133*Mn%*Mo%

the amounts of elements are expressed in mass percentages.

Preferably, the resistance spot welding seam of two steel parts from the steel sheet according to the invention is characterized by an α value of at least 30 daN/mm ² .

The object of the present invention is achieved by obtaining a steel sheet according to claim 1. The steel sheet may also include any characteristics of any of claims. 2 - 10, taken individually or in combination.

Another object of this invention is a resistance spot welding seam of two steel parts according to claim 11.

The invention will now be described in detail and illustrated by examples without limitation.

According to the invention, the carbon content is from 0.03% to 0.18% to ensure satisfactory strength and good weldability characteristics. When the carbon content is higher than 0.18%, the weldability of the steel sheet and the resistance to LME may be reduced. The simmering temperature depends on the carbon content: the higher the carbon content, the lower the simmering temperature to stabilize austenite. If the carbon content is below 0.03%, the strength of the annealed martensite is insufficient to achieve a TS value above 900 MPa. In a preferred embodiment of the invention, the carbon content is from 0.05% to 0.15%. In another preferred embodiment of the invention, the carbon content is from 0.08 to 0.12%, or even better, from 0.08 to 0.10%.

Manganese content ranges from 6.0% to 11.0%. When adding more than 11.0%, the weldability of the steel sheet and the productivity of assembly of parts may decrease. In addition, the risk of axial segregation increases to the point of causing detrimental effects on mechanical properties. Since the simmering temperature largely depends on the manganese content, the minimum amount of manganese is determined to stabilize austenite in order to obtain the desired microstructure and strength after simmering. Preferably, the manganese content is from 6.0% to 9%.

According to the invention, the aluminum content is from 0.2% to 3% to reduce manganese segregation during casting. Aluminum is a very effective element for deoxidizing steel when processed in the liquid phase. When adding more than 3%, the weldability of the steel sheet in the immediately after casting state may decrease. In addition, it is difficult to achieve a tensile strength higher than 900 MPa. In addition, the higher the aluminum content, the higher the simmering temperature to stabilize austenite. Aluminum is added in amounts of at least up to 0.2% to improve the product's resistance to changes by increasing the intercritical range, as well as to improve weldability. In addition, aluminum can be added to avoid inclusion and oxidation problems. In a preferred embodiment of the invention, the aluminum content is from 0.2% to 2.2%, and more preferably from 0.7 to 2.2%.

The molybdenum content is 0.05% to 0.5% to reduce manganese segregation during casting. In addition, the addition of at least 0.05% molybdenum provides resistance to embrittlement. Above 0.5% addition of molybdenum is expensive and ineffective in terms of the required properties. In a preferred embodiment of the invention, the molybdenum content is from 0.15% to 0.35%.

According to the invention, the boron content is from 0.0005% to 0.005% to improve the rigidity of the hot-rolled steel sheet and the weldability of the cold-rolled steel sheet in spot welding. At contents above 0.005%, the formation of boron carbides at the preceding austenite grain boundaries is activated, which makes the steel more brittle. In a preferred embodiment of the invention, the boron content is from 0.001% to 0.003%.

Optionally, certain elements can be added to the steel composition of the invention.

The maximum addition of silicon content in order to increase resistance to LME is limited to 1.20%. In addition, this low silicon content makes it possible to simplify the process by eliminating the step of pickling the hot-rolled steel sheet before annealing the hot-rolled sheet. Preferably, the maximum silicon content added is 0.8%.

Titanium can be added up to a concentration of 0.050% to provide precipitation strengthening. Preferably, a minimum of 0.010% titanium is added in addition to boron to prevent boron from forming a BN compound.

Niobium may optionally be added to a concentration of 0.050% to refine the austenite grains during hot rolling and provide precipitation strengthening. Preferably, the minimum amount of niobium added is 0.010%.

Chromium and vanadium may optionally be added to achieve concentrations of 0.5% and 0.2%, respectively, to provide increased strength.

The remainder of the steel's composition is iron and impurities resulting from smelting. In this regard, at least P, S and N are considered to be residual elements that are unavoidable impurities. Their content is 0.010% or less for S; 0.020% or less for P and 0.008% or less for N.

Next, the microstructure of the steel sheet according to the invention will be described. It includes, in surface fractions:

- from 0% to 45% ferrite,

- from 20% to 50% retained austenite,

- from 5 to 80% annealed martensite,

- less than 5% fresh martensite,

- content of carbon [C] _A and manganese [Mn] _A in austenite, expressed in mass. % is such that the ratio ([C] _A² x [Mn] _A ) / (C%² x Mn%) is from 4.5 to 11.0, with C% and Mn% representing the nominal values of carbon content and manganese in mass percent in steel and

- the density of carbides is below 4x10 ⁶ /mm².

The microstructure of the steel sheet according to the invention contains from 20% to 50% retained austenite. At austenite concentrations below 20%, the uniform elongation UE cannot reach the minimum value of 11.0%. At concentrations above 50% the yield strength is below 700 MPa.

Such austenite may be formed during intercritical annealing of a hot-rolled steel sheet, as well as during the first annealing of a cold-rolled steel sheet or the second annealing as a result of the transformation of part of the martensite at high temperature.

The concentrations of carbon [C] _A and manganese [Mn] _A in austenite, expressed as percent by weight, are such that the ratio ([C] _A² x [Mn] _A ) / (C%² x Mn%) is between 4. 5 to 11.0, with C% and Mn% representing the nominal values of the C and Mn content of the steel in mass percent. This formula shows the level of release of carbon and manganese into retained austenite. When the specified ratio is less than 4.5, the yield strength cannot reach the minimum level of 700 MPa. When this ratio is greater than 11.0, the retained austenite is too stable to exhibit adequate TRIP-TWIP effect upon deformation. This TWIP-TRIP effect is explained, in particular, in the work “Observation-of-the-TWIP-TRIP-Plasticity-Enhancement-Mechanism-in-Al-Added-6-Wt-Pct-Medium-Mn-Steel”, DOI : 10.1007/s11661-015-2854-z, The Minerals, Metals & Materials Society and ASM International 2015, p. 2356Volume 46A, June 2015 (S. LEE, K. LEE, and BC DE COOMAN).

The microstructure of the steel sheet according to the invention contains from 0 to 45% ferrite. Such ferrite may be formed during the first annealing of the cold-rolled steel sheet when it occurs at a temperature below the Ac3 temperature of the cold-rolled steel sheet. When the first annealing of the cold-rolled steel sheet is carried out at a temperature above the Ac3 value of the cold-rolled steel sheet, no ferrite is present. In a preferred embodiment, such ferrite recrystallizes and exhibits equiaxed grains with an aspect ratio of less than 2.

The microstructure of the steel sheet according to the invention contains from 5 to 80% annealed martensite. Such martensite can form during cooling of a hot-rolled steel sheet after intercritical annealing due to the transformation of a part of the austenite that is less enriched in carbon and manganese compared to the nominal values. However, it is mainly formed when the cold-rolled steel sheet is cooled after the first annealing, and then annealed during the second annealing of the cold-rolled steel sheet. Such annealed martensite may be tempered martensite and/or regenerated and/or recrystallized martensite. When the second annealing is carried out in a lower temperature range, the martensite may preferably be tempered martensite and regenerated martensite. When the second annealing is carried out in a higher temperature range, the martensite may preferably be regenerated and recrystallized martensite.

Fresh martensite may be present in an amount of less than 5% in surface fractions, but it is not a phase desired in the microstructure of the steel sheet according to the invention. It can form during the final stage of cooling to room temperature as a result of the transformation of unstable austenite depleted in manganese and carbon. Indeed, the mentioned unstable austenite with low carbon and manganese content leads to the fact that the initial temperature of martensite formation, Ms, is above 20°C. To achieve the final mechanical properties, the fresh martensite content should be less than 5%, preferably less than 3%, or better yet, reduced to 0%.

Finally, the carbide density must be kept below 4x10 ⁶ /mm² to ensure that the value of the expression [(YS-200)xUE+(TS-300)xTE]/(C%xMn%) remains greater than 29,000.

In the first embodiment, the microstructure includes 5% to 25% ferrite, 25% to 50% retained austenite, and 25% to 70% annealed martensite.

In another embodiment, the microstructure contains no ferrite and includes 25% to 45% retained austenite and 55% to 75% annealed martensite.

The steel sheet according to the invention is characterized by tensile strength, TS, equal to 900 MPa or higher, uniform elongation UE equal to 11% or higher, yield strength equal to 700 MPa or higher, and corresponds to the expression [(YS-200)xUE+(TS -300)xTE]/(C%xMn%) greater than 29,000, with TE representing the total elongation of the sheet.

Preferably, the steel sheet has a total elongation TE of 15.0% or more.

Preferably, the steel sheet according to the invention has an LME propensity index of less than 0.36.

Preferably, the steel sheet according to the invention has a carbon equivalent Ceq of less than 0.4%, the carbon equivalent being defined as follows:

Ceq = C%+Si%/55+Cr%/20+Mn%/19-Al%/18+2.2P%-3.24B%-0.133*Mn%*Mo%,

in this case, the concentrations of elements are expressed in mass percent.

A welded structure can be produced by producing two parts from steel sheets according to the invention, and then performing resistance spot welding of the two steel parts.

The resistance spot weld seams connecting the first sheet to the second sheet are characterized by high resistance in the tensile test on a cross-shaped specimen, determined by an α value of at least 30 daN/mm ² .

The steel sheet according to the invention can be produced by any suitable manufacturing method and can be determined by one skilled in the art. However, it is preferable to use the method according to the invention, comprising the following steps:

A semi-product is obtained that can be subjected to further hot rolling, with the steel composition described above. This intermediate product is heated to a temperature of from 1150°C to 1300°C to facilitate hot rolling with a final hot rolling temperature, FHT, ranging from 800°C to 1000°C. Preferably, the temperature of the PSC is from 850°C to 950°C.

The hot rolled steel sheet is then cooled and coiled at a temperature _Troll of 20°C to 650°C, preferably 300 to 500°C.

The hot rolled steel sheet is then cooled to room temperature and can be pickled.

Then, the hot-rolled steel sheet is heated to an annealing temperature _TOGL , which is in the range of a temperature Tc to 680°C. The Tc value corresponds to the temperature at which carbides completely dissolve and can be determined using FEG-SEM studies after heat treatment. Annealing in the specified range will minimize the surface area occupied by precipitated carbides and activate the re-precipitation of manganese into austenite. In addition, at temperatures below 680°C the microstructure does not coarse. The temperature Tc is higher than the Ac1 temperature, since Tc is the boundary line between the three-phase ferrite/austenite/carbides region and the two-phase ferrite/austenite region, which is above the Ac1 temperature, since Ac1 is the boundary line between the ferrite/carbide region and the ferrite/austenite/carbides region. Preferably, the temperature _TOGL is from 600°C to 680°C.

The steel sheet is maintained at the specified temperature _TOGL for a holding time period, _TOGL , ranging from 0.1 to 120 hours to activate the diffusion of manganese. In addition, the specified heat treatment of hot-rolled steel sheet makes it possible to reduce hardness while maintaining its toughness.

The hot-rolled and heat-treated steel sheet is then cooled to room temperature and can be pickled to eliminate oxidation.

After this, cold rolling of hot-rolled and heat-treated steel sheet is carried out with a reduction degree from 20% to 80%.

Next, the cold-rolled steel sheet is first annealed at a temperature _T1 of (Ac1+Ac3)/2 to (Ac3+80) for a holding time _t1 of 10 s to 1800 s. If T ₁ is higher than the specified limit, an insufficient amount of austenite may be stabilized at room temperature. Preferably, T ₁ is from 720 to 900°C and more preferably from 720°C to 870°C, and the time t ₁ is from 100 to 1000 s. Such annealing can be performed in continuous annealing mode.

The cold-rolled and annealed steel sheet is then cooled to a temperature below 80°C, preferably with an average cooling rate of at least 0.1°C/s, and preferably at least 1°C/s. After this, the microstructure of the sheet consists of austenite and martensite, and may also contain ferrite if the annealing temperature was below the Ac3 value. Such ferrite will not be present if annealing is performed at a temperature above Ac3.

After cooling, a second annealing step of the steel sheet is then carried out at a temperature T ₂ of 350 to 650°C for a time period t ₂ of 1 to 100 hours. Preferably, T ₂ is 400 to 650°C and t ₂ is from 1 to 50 hours. This stage can be carried out in the periodic annealing mode.

The main purpose of the second annealing is to temper the martensite at the beginning of the annealing when the temperature is still low. Then, as the temperature rises, the re-precipitation of carbon and manganese into austenite from the adjacent martensite continues. Finally, when the temperature reaches _T2 , some of the martensite transforms into austenite.

The temperature T ₂ of the second annealing depends on the chemical composition, the conditions of the intermediate periodic annealing and the first annealing. It must be low enough to limit the formation of unstable austenite, which would then transform into fresh martensite with little deformation, which leads to both a decrease in yield strength and a reduction in elongation. It must be low enough to avoid the formation of unstable austenite, which would transform into fresh martensite on final cooling, resulting in a reduction in elongation. It must be high enough to avoid the formation of too many carbides, which consume carbon and manganese and lead to a decrease in strength. Said formation of carbides can occur especially when the second annealing temperature T ₂ is below the Tc value of the steel sheet.

The temperature T ₂ of the second annealing should also be high enough to avoid the formation of too stable austenite, which leads to a decrease in elongation due to the absence of the TRIP-TWIP effect.

The cold-rolled and double-annealed steel sheet is then cooled to room temperature, and during such cooling a small proportion of fresh martensite may be formed as a result of the transformation of a portion of the austenite depleted in manganese and carbon.

The sheet may then be coated by any suitable method, including hot dip coating, electrodeposition, or vacuum deposition of zinc or zinc-based alloys, or aluminum or zinc-based alloys.

The invention will now be illustrated by the following examples, which are in no way limiting.

Examples

Three grades of steel, the compositions of which are given in Table 1, were cast in the form of semi-finished products and processed into steel sheets.

Table 1. Compositions

The tested formulations are summarized in the following table, in which the elemental contents are expressed as percentages by weight.

The Ac1 and Ac3 temperatures of cold-rolled sheets were determined using dilatometric tests and metallographic analysis.

Table 2. Process parameters for producing hot-rolled and heat-treated steel sheets

Directly after casting, the steel semi-products were reheated at 1200°C, hot rolled, and then coiled. After this, hot-rolled and coiled steel sheets are subjected to heat treatment at temperature _TOGL and maintained at the specified temperature during the holding time, _tOGL. The following specific conditions were used to obtain hot-rolled and heat-treated steel sheets:

Underlined values: parameters that do not allow achieving the specified properties

Table 3. Process parameters for producing cold-rolled, double-annealed steel sheets

Then cold rolling of the resulting hot-rolled and heat-treated steel sheet is carried out. Thereafter, the cold-rolled steel sheet is first annealed at a temperature T ₁ and maintained at the specified temperature for a holding time period, t ₁ , before being cooled at a cooling rate of 2°C/s. Next, the steel sheet is heated a second time at a temperature T ₂ and maintained at this temperature for a holding time period, t ₂ , before cooling to room temperature. The following specific conditions were used to produce cold-rolled and annealed steel sheets:

Underlined values: parameters that do not allow achieving the specified properties

The cold-rolled and annealed sheets were then analyzed, and the corresponding data regarding microstructural elements, mechanical properties and weldability characteristics are shown in Tables 4, 5 and 6, respectively.

Table 4. Microstructure of cold-rolled and double-annealed steel sheet

The phase percentages of the microstructures of the resulting cold-rolled and double-annealed steel sheets were determined.

The values of [C] _A and [Mn] _A correspond to the amounts of carbon and manganese in austenite, expressed as percentages by mass. They are measured by X-ray diffraction in the case of carbon, C%, and using an electron probe microanalyzer with a field emission gun in the case of manganese, Mn%.

The proportions of phases on the surface of the microstructure are determined in the following way: to identify the microstructure, a test sample is cut from a cold-rolled and double-annealed steel sheet, polished and etched with a reagent known for such quality. The excised sample is then examined using a scanning electron microscope, such as a field emission gun scanning electron microscope (“FEG-SEM”), at a magnification greater than 5000x, in secondary electron mode.

Annealed martensite can differ from fresh martensite in morphology: annealed martensite has a smooth surface, sometimes with carbides inside, in contrast to fresh martensite, which has a rough surface and contains no carbides.

Determination of the proportion of ferrite on the surface is carried out using SEM studies after etching with Nital or Picral/Nital reagents.

Determination of the volume fraction of retained austenite is performed by X-ray diffraction.

The density of the precipitated carbides is determined through a sample cut from the sheet, examined using a field emission gun scanning electron microscope (“FEG-SEM”) and image analysis at magnifications greater than 15,000x.

Table 5. Mechanical properties of cold-rolled, double-annealed steel sheet

The mechanical properties of the resulting cold-rolled, double-annealed steel sheets are determined and shown in the table below.

Yield strength, YS, tensile strength, TS, and uniform and total elongation UE, TE, were measured in accordance with ISO 6892-1 published in October 2009.

Underlined values: do not correspond to the specified values

In tests 1, 2, 3, 4, 8, 19, 26, 27 and 28, the sheets were exposed to temperatures T ₂ that were too low. The resulting austenite is too stable, as demonstrated by the exponent value ([C] _A² x [Mn] _A )/(%C² x %Mn) which is too high, resulting in reduced uniform elongation.

In contrast, in Tests 5, 9, 18, 24 the sheets were exposed to a temperature T ₂ that was high enough to ensure that the austenite stability was at a specified value, resulting in very good uniform and total elongation values.

In addition, in tests 19, 25, 26, 27 and 28, the sheets were exposed to temperatures T ₂ that were below Tc, and included too many carbides beyond the maximum allowable value of 4x10 ⁶ /mm².

In tests 10, 11, 12, 20 and 21, the sheets were exposed to temperatures T ₂ that were too high. The resulting austenite is too unstable, as demonstrated by the index value ([C] _A² x [Mn] _A )/(%C² x %Mn) which is too low, resulting in a decrease in yield strength. In addition, all of these tests demonstrated the formation of some fresh martensite, with tests 10, 11 and 20 exceeding the maximum allowable value of 5%. In contrast, in Tests 13 and 22, the sheets were exposed to a temperature T ₂ that was low enough to ensure that austenite stability was at a target value resulting in very good performance without the formation of fresh martensite.

Table 6. Weldability characteristics of cold-rolled, double-annealed steel sheet

Spot welding was performed on cold-rolled, double-annealed steel sheets under ISO 18278-2 conditions.

In the test used, the specimens consist of two sheets of steel in the form of a cross-welded equivalent. Force is applied to break the weld point. The specified force, known as the cross-shaped tensile strength (CTS), is expressed in units of daN. It depends on the diameter of the weld point and the thickness of the metal, that is, the thickness of the steel and metal coating. This makes it possible to calculate the coefficient α, which is the ratio of the CTS value to the product of the diameter of the weld spot and the thickness of the base. The specified coefficient is expressed in units of daN/mm².

The weldability characteristics of cold-rolled and double-annealed steel sheets are determined and summarized in the following table:

Tests α (daN/mm²) LME propensity score 1 60 0.068 2 60 0.068 3 60 0.068 4 60 0.068 5 60 0.068 6 63 0.090 7 63 0.090 8 63 0.090 9 63 0.090 10 40 0.157 eleven 40 0.157 12 40 0.157 13 40 0.157 14 40 0.157 15 40 0.157 16 40 0.157 17 40 0.157 18 40 0.157 19 40 0.157 20 40 0.157 21 40 0.157 22 40 0.157 23 40 0.157 24 40 0.157 25 40 0.157 26 40 0.157 27 40 0.157 28 40 0.157

LME propensity index = C% + Si%/4, in mass. %.

Claims (38)

1. Cold-rolled and double-annealed steel sheet made of steel having the composition, in wt.%: C: 0.03- 0.18 Mn: 6.0 – 11.0 0.2 ≤ Al < 3 Mo: 0.05 – 0.5 B: 0.0005 – 0.005 S ≤ 0.010 P ≤ 0.020 N ≤ 0.008 and optionally including one or more of the following: Si ≤ 1.20 Nb ≤ 0.050 Ti ≤ 0.050 Cr ≤ 0.5 V ≤ 0.2, while the rest of the composition consists of iron and inevitable impurities formed during smelting, the said steel sheet has a microstructure containing, in surface fractions: from 0 to 45% ferrite, from 20 to 50% retained austenite, from 5 to 80% annealed martensite, from 0 to 5% fresh martensite, carbide density below 4×10 ⁶ /mm ² , in this case, the ratio ([C] _A ² x [Mn] _A ) / (C% ² x Mn%) is satisfied, ranging from 4.5 to 11.0, where [C] _A and [Mn] _A are the content of carbon and manganese in austenite, expressed in mass percent, C% and Mn% - nominal values of the C and Mn content in steel, in wt.%. 2. Steel sheet according to claim 1, characterized in that the carbon content is from 0.05 to 0.15 wt.%. 3. Steel sheet according to claim 1 or 2, characterized in that the manganese content is from 6.0 to 9 wt.%. 4. Steel sheet according to any one of paragraphs. 1 – 3, characterized in that the aluminum content is from 0.2 to 2.2 wt.%. 5. Steel sheet according to any one of paragraphs. 1 – 4, characterized in that the microstructure contains from 5 to 25% ferrite, from 25 to 50% retained austenite and from 25 to 70% annealed martensite. 6. Steel sheet according to any one of paragraphs. 1 – 5, characterized in that ferrite is present and is equiaxed. 7. Steel sheet according to any one of paragraphs. 1 – 5, characterized in that the microstructure does not contain ferrite and contains from 25 to 45% retained austenite and from 55 to 75% annealed martensite. 8. Steel sheet according to any one of paragraphs. 1 to 7, characterized in that the tensile strength is 900 MPa or more, the elongation UE is 11% or more, the yield strength YS is 700 MPa or more, and the total elongation TE, YS, UE, TS are such that the value the ratio [(YS-200)xUE+(TS-300)xTE]/(C%xMn%) is more than 29,000. 9. Steel sheet according to any one of paragraphs. 1 – 8, characterized in that the susceptibility index to liquid metal embrittlement (LME) is less than 0.36. 10. Steel sheet according to any one of paragraphs. 1 – 9, characterized in that the steel is characterized by a carbon equivalent Ceq, which is less than 0.4%, and the carbon equivalent is determined as follows: Ceq = C%+Si%/55+Cr%/20+Mn%/19-Al%/18+2.2P%-3.24B%-0.133xMn%xMo%, the amounts of elements are expressed in mass percentages. 11. Seam of contact spot welding of two steel parts made of cold-rolled and double-annealed steel sheet according to any one of paragraphs. 1 – 10, characterized by an α value that is at least 30 daN/mm ² , where α is the ratio of the tensile strength, which is the force applied to destroy the weld point obtained by welding two parts, to the product of the diameter of the weld point and the thickness of the base of the seam.