CN114214563A

CN114214563A - High-toughness hot stamping steel rolled by sheet billet with Rm more than or equal to 1500MPa and production method

Info

Publication number: CN114214563A
Application number: CN202111484332.8A
Authority: CN
Inventors: 葛锐; 杨睿; 刘静; 张施琦
Original assignee: Wuhan University of Science and Engineering WUSE
Current assignee: Wuhan University of Science and Engineering WUSE
Priority date: 2021-12-07
Filing date: 2021-12-07
Publication date: 2022-03-22
Anticipated expiration: 2041-12-07
Also published as: CN114214563B

Abstract

The high-toughness hot stamping steel with the Rm more than or equal to 1500MPa rolled by a sheet billet comprises the following components in percentage by weight: 0.23-0.27% of C, Si: 0.11 to 0.30%, Mn: 4.4-5.3%, P is less than or equal to 0.005%, S is less than or equal to 0.005%, Als: 2.4-3.2%, N: 0.002-0.008%, V: 0.10 to 0.25%, Ti: 0.018-0.030% or Nb: 0.015-0.030% or a mixture of the two in any proportion; the production method comprises the following steps: conventional smelting and refining; continuously casting into a blank; descaling before entering a soaking pit; heating and soaking; descaling by high-pressure water before rolling; rolling; cooling; coiling; hot stamping and heating treatment; and (6) stamping and forming. The invention can ensure that the tensile strength is not lower than 1500MPa, the yield strength is not lower than 930MPa, the hot stamping forming has no resilience, and the elongation rate reaches more than 10 percent on the premise of high dimensional precision of parts, thereby meeting the requirement of automobile light weight on the elongation rate under ultrahigh strength.

Description

High-toughness hot stamping steel rolled by sheet billet with Rm more than or equal to 1500MPa and production method

Technical Field

The invention relates to steel for automobile parts and a production method thereof, in particular to high-toughness hot stamping steel with Rm more than or equal to 1500MPa rolled by a sheet billet and a production method thereof, and the steel is suitable for producing products with the thickness of 0.5-2 mm.

Background

The light weight of the automobile body is an important way for saving energy and reducing emission of the automobile; as a main raw material for manufacturing a vehicle body, the strength and plasticity of the automobile steel are improved, and the automobile steel has important application value for improving the lightweight level and the passive safety performance of the automobile. At present, developed third-generation ultrahigh-strength steel has ultrahigh material strength and high toughness, but parts of the steel have the problems of high forming pressure, complex forming process, severe die abrasion, part springback and the like in stamping and forming.

The hot stamping forming technology utilizes the good formability of metal materials in a high-temperature state, effectively reduces the processing deformation resistance, improves the size precision of parts and the service life of a die, and is highly favored by domestic and foreign vehicle enterprises. However, the traditional hot forming steel is designed mainly from the hardenability of steel, so as to ensure that the part is quenched to form a full martensite structure in the forming and cooling process in the die, and the part strength reaches more than 1500 MPa. A hot-formed part with a fully martensitic structure, although achieving high strength, is less plastic. At present, the post-fracture elongation of the existing hot forming steel with the tensile strength of 1500MPa at home and abroad is lower than 10%, and the steel cannot effectively absorb the automobile collision energy, so that the steel gradually becomes a bottleneck for restricting the application proportion of the traditional hot forming steel in an automobile body. The method improves the toughness and the product of strength and elongation of the hot forming steel and the parts thereof, synchronously realizes ultrahigh strength and high toughness, and is an important direction for the research of the hot forming steel for the automobiles at present.

In addition, the raw material cost is a key issue for the mass application of hot formed steel. The production process flow of the traditional hot forming steel is as follows: desulfurized molten iron → converter smelting → external refining → continuous casting → heating of plate blank → hot continuous rolling → acid pickling + cold continuous rolling → continuous annealing → (pre-coating) → finishing packaging → blanking → heating → die press quenching; it has the disadvantages of longer production process flow and higher cost. In recent years, the continuous casting and rolling process of medium and thin slabs develops and matures gradually, and the product quality is greatly improved; the traditional cold-rolled hot-formed steel can be replaced by a short-flow continuous casting and rolling process, and the ultrahigh-strength steel plate is directly rolled, so that the production cost of the raw material steel plate is greatly reduced. For example, in the document of chinese patent publication No. CN 105441786a, a thin steel sheet for hot stamping forming with tensile strength of 1500MPa level and a production method thereof are developed by using a short continuous casting and rolling process, and the thin steel sheet comprises the following components in percentage by weight: c: 0.20 to 0.25%, Si: 0.25 to 0.40%, Mn: 1.00-1.30%, P: less than or equal to 0.025 percent, S: less than or equal to 0.01 percent, Als: 0.015-0.035%, N: less than or equal to 0.005 percent, B: less than or equal to 0.005 percent, Nb: 0.020 to 0.060%, Ti: 0.01-0.04%, and the balance of iron and inevitable trace elements. After smelting, casting the smelted product into a thin slab, descaling, heating and hot rolling, wherein the initial rolling temperature is controlled to be not lower than 1200 ℃, the final rolling temperature is controlled to be 870-920 ℃, and the coiling temperature is controlled to be 680-730 ℃. The tensile strength of the hot formed product is more than or equal to 1500MPa, and the elongation is 7.2-7.8%; the full martensite structure shape limits the further improvement of the extensibility.

Chinese patent publication No. CN 106086685A discloses a hot-formed steel with tensile strength more than or equal to 1500MPa directly rolled by a thin slab, which comprises the following chemical components in percentage by mass: 0.21-0.25% of C, Si: 0.26-0.30%, Mn: 1.0-1.3%, P is less than or equal to 0.01%, S is less than or equal to 0.005%, Als: 0.015 to 0.060%, Cr: 0.25-0.30%, Ti: 0.026-0.030% or Nb: 0.026-0.030% or V: 0.026-0.030% or a mixture of two or more thereof at an arbitrary ratio, B: 0.003-0.004%, N is less than or equal to 0.005%, and the balance of Fe and inevitable impurities; after smelting, casting a casting blank with the thickness of 52-55 mm, descaling, heating and rolling, and controlling the final rolling temperature to 850-890 ℃; and (4) cooling and then coiling, wherein the coiling temperature is controlled to be 655-675 ℃. The part obtained after hot forming is also of a full martensite structure, the tensile strength is more than or equal to 1500MPa, the elongation is only 6.4-7.5%, and the toughness is poor.

The tensile strength of the materials in the two documents can reach 1500MPa or above, but the elongation of the materials is not more than 8 percent and is far lower than 10 percent, so the requirements of automobile light weight on 1500 MPa-grade high-toughness ultrahigh-strength materials cannot be met. The steel is a part which is transformed into a full-martensite structure through hot stamping mainly from the design of improving the hardenability of the steel, and has lower toughness; the energy absorption effect is poor in the collision process, the materials are easy to crack and lose effectiveness, and the collision safety is generally improved by increasing the material thickness and compensating in a local tempering or laser tailor-welding high-toughness material mode. The high-toughness ultrahigh-strength steel has ultrahigh strength and high plasticity, the thickness of parts is directly further reduced on the basis of the traditional hot forming parts, the production cost is reduced, the weight of the automobile body is reduced, and the high-toughness ultrahigh-strength steel can be used for processing and manufacturing safety components such as automobile body bumpers, longitudinal beams, A/B columns and the like.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides the high-toughness hot stamping steel with the tensile strength of 1500MPa and the production method, wherein the high-toughness hot stamping steel can ensure that the tensile strength is not lower than 1510MPa, the yield strength is not lower than 910MPa, the steel has no resilience after hot stamping forming and the elongation of the steel can reach more than 10.5 percent on the premise of high dimensional precision of parts.

The measures for realizing the aim are as follows:

the high-toughness hot stamping steel with the Rm more than or equal to 1500MPa rolled by a sheet billet comprises the following components in percentage by weight: 0.23-0.27% of C, Si: 0.11 to 0.30%, Mn: 4.4-5.3%, P is less than or equal to 0.005%, S is less than or equal to 0.005%, Als: 2.4-3.2%, N: 0.002-0.008%, V: 0.10 to 0.25%, Ti: 0.018-0.030% or Nb: 0.015-0.030% or a mixture of the two in any proportion, and the balance being Fe and inevitable impurities; the quenched metallographic structure comprises martensite, ferrite and austenite with the volume ratio of not less than 3%; tensile strength is more than or equal to 1500MPa, yield strength is more than or equal to 930MPa, and elongation percentage A after fracture_50mm≥10%

Preferably: the Mn content is 4.6-5.1% by weight.

Preferably: the weight percentage content of the Als is 2.6-3.0%.

The method for rolling high-toughness hot stamping steel with Rm more than or equal to 1500MPa by using a thin slab for production comprises the following steps:

1) conventional smelting and refining;

2) continuously casting into a blank, and controlling the superheat degree of tundish molten steel to be 15-30 ℃ in the casting process; controlling the thickness of a casting blank to be 45-60 mm, and controlling the blank drawing speed to be 4.2-8.0 m/min;

3) carrying out descaling treatment before the casting blank is placed into a soaking pit furnace, and controlling the pressure of descaling water to be 300-400 bar;

4) heating and soaking a casting blank: controlling the charging temperature of the casting blank to be 871-1000 ℃, and the discharging temperature of the casting blank to be 1196-1254 ℃;

5) carrying out high-pressure water descaling before rolling, and controlling the pressure of the descaling water to be 280-420 bar;

6) rolling, and controlling the first pass reduction rate to be 50-68%, the second pass reduction rate to be 48-60% and the last pass reduction rate to be 8-15%; controlling the rolling speed to be 8-15 m/s; performing medium-pressure water descaling between the first pass and the second pass, wherein the pressure of the descaling water is 200-280 bar; controlling the finishing temperature to be 856-892 ℃;

7) cooling to the coiling temperature in a laminar flow cooling mode, a water curtain cooling mode or an encryption cooling mode;

8) coiling, and controlling the coiling temperature to be 549-602 ℃;

9) carrying out hot stamping heating treatment after uncoiling and blanking, controlling the heating temperature to be 930-960 ℃, and preserving heat for 3-8 min at the temperature;

10) performing press forming: maintaining the pressure in the die for 10-25 s, quenching, cooling to below 200 ℃ at the quenching speed of 30-75 ℃/s, and naturally cooling to room temperature.

Preferably: the discharging temperature of the casting blank is 1201-1249 ℃.

Preferably: the finishing temperature is 863-886 ℃.

Preferably: the coiling temperature is 556-602 ℃.

Preferably: the temperature of the hot stamping and heating treatment is 936-950 ℃.

Preferably: and cooling the steel plate to below 150 ℃ at the quenching speed of 42-74 ℃/s.

The process flow of the invention is short flows of CSP, ESP, MCCR and the like.

The action and mechanism of each element and main process in the invention

C: carbon is an essential element in steel and is also the most economical and effective strengthening element. The carbon content is designed to be lower, and the strength is reduced after hot stamping forming; however, too high a carbon content lowers the plasticity of the steel and is disadvantageous in weldability. Therefore, in the invention, the control range of the C content is 0.23-0.27% from the aspects of economy and comprehensive performance.

Si: silicon can improve the hardenability of steel and has the function of reducing the volume change when the austenite is transformed into martensite, thereby effectively controlling the generation of quenching cracks; with the increase of the silicon content, the strength of the steel is obviously improved, the plasticity is obviously reduced, and the welding performance is reduced. Therefore, the content is limited to 0.11 to 0.30%.

Mn: manganese is a strong austenite stabilizing element of the material. In the heating and heat-preserving stage before hot forming, Mn element is continuously reversely transformed into austenite and enriched in the plate, so that the stability of austenite and the content at room temperature can be improved, and the improvement of the plasticity and the toughness of parts is facilitated. The Mn element is a solid solution strengthening element at the same time, the strength of the medium manganese steel matrix structure can be obviously improved, and the content of the Mn element needs to be controlled to be 4.6 percent or more. In addition, the casting blank is obtained by a thin slab continuous casting and rolling process, is thinner than a conventional hot rolled sheet, and has the quality problems of edge cracking and the like of a hot rolled steel coil easily caused by excessively high content of Mn element, so that the Mn content is limited to be not more than 5.5 percent. Therefore, in order to obtain the tensile strength of more than 1500MPa and the elongation after fracture of more than 10 percent, the invention limits Mn to be 4.4-5.3 percent through a plurality of tests, and the Mn content is preferably 4.6-5.1 percent by weight.

And Als: the aluminum element is a ferrite forming element which can inhibit the precipitation of carbides and promote the reverse austenite enrichment of the C element to the strip steel. The addition of the aluminum element is beneficial to widening the two-phase critical interval of austenite and ferrite, reducing the tissue sensitivity caused by temperature fluctuation in the heating treatment stage of the hot forming raw material and improving the performance stability of the hot forming part; however, excessive addition of Al element may decrease the strength of the medium manganese steel sheet and may easily cause a sticking alarm during continuous casting of molten steel. Therefore, the content is limited to 2.4 to 3.2%.

P: phosphorus is a harmful element in steel and is easy to cause center segregation of a casting blank. The steel is easy to be deviated to a grain boundary in the subsequent heating process of the hot continuous rolling of the strip steel, so that the brittleness of the steel is obviously increased. Meanwhile, the content is controlled to be below 0.005 percent based on cost consideration and without influencing the performance of the steel.

S: sulfur is a very harmful element. Sulfur in steel often exists in the form of sulfide of manganese, and this sulfide inclusion deteriorates toughness of steel and causes anisotropy of properties, so that the lower the sulfur content in steel, the better. The sulfur content in steel is controlled to 0.005% or less in consideration of the manufacturing cost.

N: the nitrogen can be combined with vanadium and titanium in the titanium-added steel to form vanadium nitride and titanium nitride, and the second phase precipitated at high temperature is favorable for strengthening a matrix and improving the strength of the material. But the content of N is higher than 0.008 percent, the solubility product of N and Ti is higher, titanium nitride with coarse particles can be formed in the steel at high temperature, and the plasticity and the toughness of the steel are seriously damaged; in addition, higher N content increases the amount of micro-alloying elements needed to stabilize it, thereby increasing costs. Therefore, the content is controlled to be 0.002-0.008%.

Ti: titanium is a strong C, N-forming element, and the purpose of adding Ti to the steel is to fix the N element in the steel, but excess Ti will combine with C and reduce the hardness and strength of the martensite after quenching of the test steel. In addition, the addition of titanium contributes to the hardenability of the steel to some extent. Therefore, the content is limited to 0.018 to 0.030%.

Nb: niobium is a strong C, N-compound forming element and can play a role in refining austenite grains, and a certain amount of niobium carbonitride can be formed by adding a small amount of niobium into steel, so that the austenite grains are prevented from growing, therefore, the quenched martensite lath has a small size, and the strength of the steel is greatly improved. Therefore, the content is controlled to be 0.015-0.030%.

V is also a strong C, N compound forming element and can play a role in refining austenite grains, and a proper amount of vanadium is added into steel to form a certain amount of niobium or vanadium carbonitride so as to prevent the austenite grains from growing, so that the quenched martensite lath has a smaller size, and the strength of the steel is greatly improved. Meanwhile, when the vanadium is subjected to heating treatment on the hot-formed steel plate, a nano precipitated phase is preferentially formed on the surface of the ferrite, so that the ferrite strength and the yield strength of the material are effectively improved. Therefore, the content is controlled to be 0.10-0.25%.

According to the invention, the thickness of the casting blank is controlled to be 45-60 mm, the blank drawing speed is controlled to be 4.2-8.0 m/min, and the essential grain refining of the material structure of the 0.5-2 mm thin plate finished product is realized through proper plate blank thickness and hot rolling large reduction deformation, so that the comprehensive mechanical property of the thin plate finished product is improved. The pulling speed is selected mainly from the two aspects of ensuring the full solidification of the slab core and the production efficiency of products; the high stretching is beneficial to improving the production efficiency, but the premise is that the core part of the plate blank must be fully solidified, and the accidents of plate blank cracking and steel exposure caused by the high stretching are avoided.

The method controls the tapping temperature of the casting blank to be 1196-1254, preferably 1201-1249 ℃, so as to ensure that the casting blank can be fully austenitized and avoid coarse internal grains and reduced mechanical properties of the material caused by overhigh temperature.

The finishing temperature is controlled to be 856-892 ℃, preferably 863-886 ℃, because the temperature is a temperature zone for balancing ferrite and austenite tissues in the material by about 50% of proportion respectively, and the temperature can be used for regulating and controlling the proportion of ferrite in the strip steel; so as to reduce the strength of the strip steel, improve the toughness of the strip steel raw material and facilitate the stamping and blanking of the strip steel before the later stage hot forming.

The coiling temperature is controlled to be 549-602 ℃, preferably 556-602 ℃, because the temperature range is suitable for the precipitation of vanadium microalloying elements in the strip steel, and the strength and the toughness of the hot forming part are improved.

The scale removal is carried out for three times in the whole production process, and because the scale removal passes and the proper scale removal water pressure are controlled, the scale on the surface of the strip steel can be removed as much as possible, so that the strip steel is ensured to have good surface quality. In addition, the uniform structure and stable performance of the strip steel can be realized by controlling the first pass reduction rate, the second pass reduction rate and the final pass reduction rate.

The heating temperature is controlled to 936-950 ℃, and the heat preservation is carried out for 3-8 min at the temperature, because the internal structure of the steel plate can realize 90-95% austenitization and a certain proportion of ferrite is reserved. After hot forming and quenching, austenite transformed martensite can ensure that the material has ultrahigh strength, and ferrite does not transform so as to improve the toughness of the material.

According to the invention, the pressure is maintained in the die for 10-30 s, then the die is quenched, and the temperature is cooled to below 150 ℃ at 42-74 ℃/s, so that the quenching treatment of the material is realized through the pressure maintaining time in the die and the actual heat exchange quenching speed of the existing die steel, and thus the high toughness and ultrahigh strength of the part are ensured. Meanwhile, the temperature of the cooled part is too high, and the size precision is easily reduced in the air cooling stage; when the temperature is cooled to a lower temperature, the pressure maintaining and cooling time needs to be increased, which is not beneficial to improving the production efficiency.

Compared with the prior art, the invention can ensure that the tensile strength is not lower than 1500MPa, the yield strength is not lower than 930MPa, no resilience exists after hot stamping forming, and the elongation of the part can reach more than 10% on the premise of high dimensional precision of the part, thereby meeting the requirement of automobile light weight on the elongation under ultrahigh strength.

Drawings

FIG. 1 is a metallographic structure of a product according to the invention;

FIG. 2 is a metallographic structure of a product of the present invention after hot stamping.

Detailed Description

The present invention is described in detail below:

table 1 is a list of values of chemical components of each example and comparative example of the present invention;

table 2 is a list of values of main process parameters of each example and comparative example of the present invention;

table 3 is a table of the performance tests of each example of the present invention and comparative example.

The preparation method comprises the following steps:

1) conventional smelting and refining;

8) coiling, and controlling the coiling temperature to be 549-602 ℃;

TABLE 1 chemical composition (wt.%) of inventive and comparative examples

TABLE 2 tabulation of values of main process parameters for each example of the invention and comparative example

TABLE 3 tabulation of mechanical Properties of each example of the invention and comparative example

As can be seen from Table 3, the tensile strength of the steel of the invention reaches more than 1500MPa and the elongation at break reaches more than 11% through a short process flow, and the steel has great significance for promoting the development of light weight of automobiles.

The present embodiments are merely preferred examples, and are not intended to limit the scope of the present invention.

Claims

1. The high-toughness hot stamping steel with the Rm more than or equal to 1500MPa rolled by a sheet billet comprises the following components in percentage by weight: 0.23-0.27% of C, Si: 0.11 to 0.30%, Mn: 4.4-5.3%, P is less than or equal to 0.005%, S is less than or equal to 0.005%, Als: 2.4-3.2%, N: 0.002-0.008%, V: 0.10 to 0.25%, Ti: 0.018-0.030% or Nb: 0.015-0.030% or a mixture of the two in any proportion, and the balance being Fe and inevitable impurities; the quenched metallographic structure comprises martensite, ferrite and austenite with the volume ratio of not less than 3%; tensile strength is more than or equal to 1500MPa, yield strength is more than or equal to 930MPa, and elongation percentage A after fracture_50mm≥10%。

2. The high-toughness hot-stamped steel rolled from a thin slab, Rm.gtoreq.1500 MPa according to claim 1, wherein: the Mn content is 4.6-5.1% by weight.

3. The high-toughness hot-stamped steel rolled from a thin slab, Rm.gtoreq.1500 MPa according to claim 1, wherein: the weight percentage content of the Als is 2.6-3.0%.

4. A method for producing a high toughness hot stamped steel rolled from a thin slab with Rm.gtoreq.1500 MPa according to claim 1, comprising the steps of:

1) conventional smelting and refining;

8) coiling, and controlling the coiling temperature to be 549-602 ℃;

5. The method of producing a high toughness hot stamping steel having a tensile strength of 1500MPa or more directly rolled from a sheet bar according to claim 4, wherein: the discharging temperature of the casting blank is 1201-1249 ℃.

6. The method for producing a high-toughness hot-stamped steel with a thin slab rolling Rm ≥ 1500MPa according to claim 4, comprising: the finishing temperature is 863-886 ℃.

7. The method for producing a high-toughness hot-stamped steel with a thin slab rolling Rm ≥ 1500MPa according to claim 4, comprising: the coiling temperature is 556-602 ℃.

8. The method for producing a high-toughness hot-stamped steel with a thin slab rolling Rm ≥ 1500MPa according to claim 4, comprising: the temperature of the hot stamping and heating treatment is 936-950 ℃.

9. The method for producing a high-toughness hot-stamped steel with a thin slab rolling Rm ≥ 1500MPa according to claim 4, comprising: and cooling the steel plate to below 150 ℃ at the quenching speed of 42-74 ℃/s.