CN111763882A

CN111763882A - Strip steel with excellent low-temperature secondary processing performance and tensile strength of 340MPa and production method thereof

Info

Publication number: CN111763882A
Application number: CN202010572388.8A
Authority: CN
Inventors: 周文强; 方芳; 唐华; 朱东风; 任彦峰
Original assignee: Wuhan Iron and Steel Co Ltd
Current assignee: Wuhan Iron and Steel Co Ltd
Priority date: 2020-06-22
Filing date: 2020-06-22
Publication date: 2020-10-13

Abstract

A steel strip with excellent low-temperature secondary processing performance and tensile strength of 340MPa comprises the following components in percentage by weight: c: 0.0008 to 0.0028%, 0.07 to 0.10% of Si, Mn: 0.20-0.40%, P0.02-0.045%, S less than or equal to 0.008%, Al: 0.02-0.045%, Ti: 0.02-0.06%, Nb: 0.006-0.022%, B: 0.0003-0.001% of N, less than or equal to 0.002%; the production steps are as follows: smelting processSmelting and casting into a blank; heating a casting blank; rough rolling; fine rolling; coiling; cold rolling after acid washing; carrying out continuous annealing treatment; slowly cooling; rapidly cooling; aging treatment; and (7) flattening. On the premise of ensuring the mechanical property, the invention ensures that the plastic strain ratio is more than or equal to 1.7 r₉₀Strain hardening index of not less than 0.19 n₉₀(ii) a The secondary processing brittleness transition temperature is stabilized at minus 60 to minus 70 ℃, the content of elements Ti and Nb is reduced, the cost is reduced by not less than 5 percent, the surface of the steel plate has no carbonized edge and bonding defects, and the steel plate is used for preparing the automobile outer covering piece used in severe cold regions.

Description

Strip steel with excellent low-temperature secondary processing performance and tensile strength of 340MPa and production method thereof

Technical Field

The invention relates to automobile steel and a production method thereof, in particular to strip steel with excellent low-temperature secondary processing performance and tensile strength of 340MPa and a production method thereof, which are particularly suitable for automobile outer covering high-strength steel applied in northern severe cold regions.

Background

With the development of light weight of automobiles, the proportion of cold-rolled high-strength steel in materials for automobile outer covers is increasing. Research shows that about 75% of oil consumption is related to the mass of the whole automobile, and the reduction of the mass of the automobile can effectively reduce the oil consumption and the emission. When the automobile quality is reduced by 10%, the oil consumption is reduced by 8%, and the emission is reduced by 4%. And the high-strength steel plate is adopted, and the original car body steel plate with the thickness of 1.0-1.2 mm can be thinned to 0.7-0.8 mm.

The secondary processing brittleness refers to a phenomenon that a steel plate is broken due to low-temperature impact in the secondary processing process after being subjected to punch forming. The susceptibility to secondary work brittleness is generally expressed in terms of ductile-brittle transition temperature. The IF steel is pure in steel quality, and solid-dissolved C and N are absent on grain boundaries, so that the bonding force between the grain boundaries is greatly reduced, and the interstitial-free steel plate is subjected to crystal fracture at low temperature and high-speed deformation, namely, the secondary processing brittleness phenomenon exists. In order to produce high-strength IF steel, P is added for solution strengthening treatment, and the phenomenon of secondary processing brittleness is more obvious because P is easy to segregate in grain boundaries, so how to effectively improve the secondary processing brittleness resistance of the material and reduce the ductile-brittle transition temperature of a steel plate so as to meet the development requirements of the automobile industry becomes the subject of research on some steel enterprises and research institutions at home and abroad.

The defects in the prior art are as follows: in some elements, because the C element is not matched and controlled with the Ti element and the Nb element, a large amount of FePTiNb composite precipitated phase is easily precipitated on a grain boundary during hot rolling, so that the secondary processing performance of the product is weakened, and the secondary processing embrittlement temperature is not lower than minus 60 ℃ or lower. More technologies in the process adopt a hood-type annealing furnace for annealing, and the hood-type annealing furnace for annealing has high cost, more importantly, surface defects such as carbonized edges, bonding and the like are easily generated on the surface, so that the surface quality requirements of an automobile outer covering part are not met, namely the defects that the surface is influenced by the macroscopic view and the surface is perfect are not allowed, such as the following searched patent documents:

the Chinese patent application No. 200610030716.1 discloses a manufacturing method for producing high-strength cold-rolled ultra-deep drawing steel plates by using a bell-type furnace, which comprises the following chemical components in percentage by mass: c is less than or equal to 0.006, Si is less than or equal to 0.30, Mn0.15-1.40, P is less than or equal to 0.08, S is less than or equal to 0.02, N is 0.001-0.005, Al is 0.03-0.06, B is 0.0003-0.002, and the addition amounts of Ti and Nb are respectively as follows: ti- (48/14) N (0.005-0.015), Nb- (93/12) C (0-0.03), and the balance Fe and inevitable impurities; smelting and casting blanks according to the components; heating at 1100-1250 ℃, rolling, and finishing rolling in a single-phase austenite area with the temperature of Ar3 or above; cold rolling, wherein the cold rolling reduction rate is more than 73%; annealing, namely annealing in a total hydrogen or nitrogen-hydrogen bell-type furnace at the temperature of 690-; and (5) flattening after annealing. The steel plate has the strength level of 390MPa, high elongation and r value and high secondary processing brittleness resistance, and the ductile-brittle transition temperature is lower than minus 40 ℃. However, the addition of Ti and Nb to the steel is not limited by S, and affects the ductile-brittle transition temperature; the cover type annealing process is adopted in the process, the cost is high, surface defects such as carbonized edges and bonding and the like are easily generated on the surface, the surface quality requirement of the automobile outer covering piece is not met, meanwhile, the ductile-brittle transition temperature of the steel is relatively high, the requirement of the automobile body for secondary processing brittleness resistance under the low-temperature environment below 60 ℃ below zero can not be met, the cost is high, more importantly, the surface defects such as the carbonized edges and the bonding and the like are easily generated on the surface, the surface quality requirement of the automobile outer covering piece is not met, and the defect that the surface is visually influenced by naked eyes to be perfect is not allowed.

A Chinese application number 201210202281.X discloses 'a hot-dip galvanized high-strength steel with a yield strength of 220MPa class', which comprises the following chemical components in percentage by weight: c: 0.0008 to 0.003%, Si:0.07 to 0.10%, Mn: 0.35-0.50%, P: 0.04-0.06%, Al: 0.015 to 0.040%, Ti: 0.02 to 0.04%, Nb: 0.020-0.035%, B: 0.0005-0.002%, S is less than or equal to 0.005%, N is less than or equal to 0.004%, O is less than or equal to 0.0030%, and the balance of Fe and inevitable impurities, and smelting and casting a blank according to the components; heating and rolling the plate blank at 1260-1290 ℃, wherein the outlet temperature of rough rolling is 1070-1090 ℃, the final rolling temperature is 910-940 ℃, laminar cooling is carried out at the cooling speed of 55-65 ℃/s, and the coiling temperature is 710-740 ℃; cold rolling, wherein the cold rolling reduction is 67-82%; continuously annealing at the annealing temperature of 815-825 ℃ at the cooling speed of 45-50 ℃/s; hot galvanizing, wherein the temperature of strip steel in a zinc pot is 460-485 ℃, and the temperature of zinc liquid is 454-466 ℃; and (4) finishing, wherein the finishing elongation is 1.2-1.4%. The hot-dip galvanized high-strength steel developed by the document has high strength, meets the requirements of the automobile industry on the strength and the rigidity of a complex structural part of an automobile body, has good deep drawing performance, can smoothly complete complex deformation, has good secondary processing brittleness resistance, has the secondary processing embrittlement temperature of below-60 ℃, and has good corrosion resistance. However, the literature fails to disclose the compounding ratio relationship between elements having a large influence on the ductile-brittle transition temperature, particularly the influence of the addition of Ti and Nb elements on the ductile-brittle transition temperature. In the literature, 0.020-0.035% of Nb element is added, excessive addition of Nb easily causes precipitation of a large amount of Nb composite phase during hot rolling, secondary processing brittleness resistance is weakened, the ductile-brittle transition temperature is increased or cannot be stably reduced to be below-60 ℃, and meanwhile, the excessive addition of Nb element increases the manufacturing cost.

Chinese patent application No. 201280064349.0 discloses a hot-dip plated high-strength steel sheet for press working, which has a tensile strength of 340MPa or more and less than 540MPa, is excellent in secondary work embrittlement resistance, low-temperature toughness of seam-welded portions, and corrosion resistance, and is applicable to fuel tanks, and which has a hot-dip plated layer formed on the surface of a cold-rolled steel sheet containing, in mass%, C: 0.0005 to 0.0050%, Si: 0.30% or less, Mn: 0.70 to 3.00%, P: 0.05% or less, Ti: 0.01 to 0.05%, Nb: 0.01 to 0.04%, B: 0.0005 to 0.0030%, S: 0.01% or less, Al: 0.01 to 0.30%, N: 0.0005 to 0.010% by mass, and the balance Fe and unavoidable impurities, [ Ti ] representing a Ti content (%), [ B ] representing a B content (%), [ P ] representing a P content (%), wherein TB defined by the following formula (A) is 0.03 to 0.06, and [ B ] and [ P ] satisfy the following formula (B). TB ═ 0.11- [ Ti ])/(ln ([ B ] × 10000)) (a); [ P ] < 10X [ B ] +0.03 (B). However, this steel is a hot-dip coated steel sheet, and the ductile-brittle transition temperature is-50 ℃ or higher, and cannot satisfy the requirement of the secondary work brittleness resistance of the vehicle body in a low-temperature environment.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the strip steel which can ensure the secondary processing brittle transition temperature to be below 60 ℃ below zero on the premise of ensuring the mechanical property, is used for preparing the strip steel with excellent low-temperature secondary processing performance and 340 MPa-level tensile strength applied in cold regions and a production method thereof.

The technical measures for realizing the purpose are as follows:

a steel strip with excellent low-temperature secondary processing performance and tensile strength of 340MPa comprises the following components in percentage by weight: c: 0.0008 to 0.0028%, 0.07 to 0.10% of Si, Mn: 0.20-0.40%, P0.02-0.045%, S less than or equal to 0.008%, Al: 0.02-0.045%, Ti: 0.02-0.06%, Nb: 0.006-0.022%, B: 0.0003-0.001%, less than or equal to 0.002% of N, and the balance of Fe and inevitable impurities; and satisfies the following conditions: ti = (48/14) N + (48/16) 1.5S + (48/12) 1.5C, Nb = (93/12) C.

Preferably: the weight percentage content of P is: 0.025 to 0.04%.

Preferably: the Mn content is 0.022-0.035% by weight.

Preferably: the weight percentage content of Ti is 0.030-0.050%.

Preferably: the Nb content is 0.010-0.018 wt%.

The method for producing the steel strip with excellent secondary processing performance at low temperature and the tensile strength of 340MPa comprises the following steps:

1) adopting desulfurized molten iron, smelting the product according to preset components and casting the product into a blank;

2) heating a casting blank: the heating temperature is controlled to be 1240-1280 ℃, and the temperature is kept for 150-200 min;

3) carrying out rough rolling, and controlling the rough rolling temperature to be 1060-1090 ℃;

4) performing finish rolling, and controlling the finish rolling temperature to be 900-940 ℃;

5) coiling, wherein the coiling temperature is controlled to be 640-680 ℃;

6) carrying out cold rolling after conventional pickling, and controlling the total reduction rate of cold rolling to be 73-82%;

7) carrying out continuous annealing treatment, wherein the continuous annealing temperature is controlled to be 815-825 ℃, and the annealing speed is controlled to be 180-250 m/min;

8) slowly cooling to 640-660 ℃ at a cooling speed of 6-11 ℃/s

9) Rapidly cooling to 440-460 ℃ at a cooling speed of 35-55 ℃/s;

10) performing overaging treatment, wherein the overaging temperature is controlled to be 430-370 ℃, and the overaging time is controlled to be 3-5 min, and the final cooling temperature is 170-180 ℃;

11) leveling is carried out, and the leveling elongation is controlled to be 0.8-1.2%.

Preferably: the continuous annealing temperature is 815-822 ℃.

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

C: carbon is a basic element in steel, and is also the most economical and effective strengthening element, and C can be segregated in grain boundaries as solid solution C, thereby suppressing secondary work brittleness of steel. However, if the C content is too high, the deep drawability of the steel is deteriorated. At the same time, excessive TiC and NbC are formed, and the TiC and NbC suppress grain growth during annealing, thereby lowering the r value. Thus, the C content is C: 0.0008 to 0.0028 percent. Si: silicon is a solid solution strengthening element, is an economical strengthening element and has strong solid solution strengthening effect. With the increase of the silicon content, the strength of the steel is obviously improved, the plasticity and the secondary processing brittleness resistance are obviously reduced, and the cold formability and the welding performance are reduced. Meanwhile, Si element easily forms a compact oxide layer Mn on the surface of the steel plate₂SiO₄Seriously affecting the surface quality of the material. Therefore, Si contentThe content of the active carbon is controlled to be 0.07-0.1%.

Mn: manganese is a relatively economic strengthening element and is mainly used for adjusting the strength of steel, the strength can be improved by 60MPa when about 1% of Mn is added, and the addition amount needs to be determined according to the strength grade of a final product. The certain amount of Mn can lower the Ar3 transformation point, lower the finishing temperature of hot rolling, and refine ferrite grains of the hot rolled steel plate, thereby improving the low-temperature toughness. And if the Mn content is too high, the toughness of the steel sheet may be reduced. Therefore, the Mn content is set to be 0.20-0.40% according to the strength grade of the product. The content of Mn in percentage by weight is preferably 0.022-0.035%.

P: phosphorus is a solid-solution strengthening element, and can greatly improve the strength and hardness of steel, but also obviously reduce the plasticity of the steel. The refining cost is increased due to the excessively low P content, and the control of the alloy cost is not facilitated due to the addition of other alloy elements. If the content of P is too high, P segregates in ferrite grain boundaries, and the grain boundary strength is lowered, thereby lowering the secondary work embrittlement resistance. Therefore, the content of P is controlled to be 0.02-0.045%, preferably 0.025-0.04% by weight, considering the contribution of P element to strength.

S: sulfur is a harmful element, and S in steel reduces plasticity and toughness of steel by forming inclusions such as MnS, and thus, the S content should be reduced as much as possible, but is controlled to not more than 0.008% in consideration of manufacturing costs required for desulfurization.

Al: in the refining step, the steel is deoxidized to remove oxygen dissolved in the molten steel, and Al suppresses solid solution of nitrogen in ferrite to form AlN to suppress coarsening of crystal grains. If the Al content is too high, inclusions in the steel increase, and the toughness of the steel decreases. Therefore, the Al content is controlled to be 0.02-0.045%.

Ti and Nb: titanium and niobium are strong C, N-forming elements, and can fix interstitial atoms C and N in steel, form fine carbonitride of Ti and Nb, and suppress coarsening of crystal grains. When the contents of Ti and Nb are too high, Ti carbonitride precipitated by Ti element in grain boundary becomes coarse, the toughness of steel is reduced, FeTiP phase is easily generated, the solid solution strengthening of P is weakened, and Nb element precipitates NbC, so that the secondary processing brittleness of steel is reduced.

The precipitates and the sequence of Ti elements in the steel are as follows: TiN, TiS, Ti4C₂S₂And TiC; while the Nb element forms mainly NbC. Therefore, the addition amounts of Ti and Nb need to satisfy: ti = (48/14) N + (48/16) 1.5S + (48/12) 1.5C, Nb = (93/12) C. Comprehensively, the content of Ti is controlled to be 0.020-0.060%, preferably the content of Ti in percentage by weight is 0.030-0.050%; the content of Nb is controlled to be 0.006-0.022%, and the content of Nb is preferably 0.010-0.018% by weight.

B: boron element inhibits P and S from segregating in the grain boundary, and effectively improves the secondary processing brittleness resistance of the steel. On the other hand, when the B content is too high, coarse BN is formed in the grain boundary, which lowers the secondary work embrittlement resistance of the steel and lowers the hot workability and toughness of the steel. Therefore, the B content is controlled to 0.0003 to 0.001%.

N: the formation of AlN by the nitrogen element suppresses the coarsening of crystal grains, but the N content is too high, and the toughness of the steel is lowered. The content of N should be reduced as much as possible, and considering the manufacturing cost, the content of N satisfies Ti = (48/14) N + (48/16) 1.5S + (48/12) 1.5C, and the content of N is reduced, thereby being beneficial to reducing the content of Ti and reducing the cost. Therefore, the N content is controlled to 0.002% or less.

According to the invention, the hot rolling coiling temperature is controlled to be 640-680 ℃, so that the coiling temperature is reduced, more solid solution carbon can be obtained, the grain boundary bonding strength is enhanced, and the ductile-brittle transition temperature is reduced, but the coiling temperature is too low, so that the precipitation of secondary phase particles in steel and the coarsening of matrix grains are not facilitated, and the deep drawing performance of a steel plate can be reduced. Comprehensively considering, the hot rolling coiling temperature is 640-680 ℃.

The invention adopts continuous annealing, on one hand, the surface quality control of the continuous annealing is better, mainly because the covering annealing is to stack the steel coils one by one, the surface quality defects such as bonding, carbonized edges and the like are easy to generate in the covering annealing furnace, and the continuous annealing is to spread the steel coils, and simultaneously the cleaning processes such as alkali cleaning, rinsing and the like are added on the surface of the steel plate, the surface of the steel coils is very smooth, the material of the invention is often used on the outer covering part of the automobile, and the requirement on the surface quality of the steel plate is higher. On the other hand, the continuous annealing has higher temperature than the cover annealing, and the high-temperature annealing can promote the formation of texture crystal grains of the matrix, increase the solid solubility of Ti and P in the matrix and hardly form a FeTiP phase. The heating time is short, the cooling speed is high, and the segregation of phosphorus in a grain boundary can be effectively reduced. In addition, the carbide is decomposed under high-temperature annealing, solid-solution carbon is increased, and the segregation of phosphorus is further reduced, so that the ductile-brittle transition temperature is reduced.

The continuous annealing temperature adopted by the invention is 815-825 ℃, and the annealing temperature is mainly increased, so that the recrystallization can be promoted, the deep drawing performance of the steel plate is improved, and the secondary processing brittleness resistance is also improved. Because the steel plate is mainly used for the automobile outer covering part, the thickness is often less than 1.0mm, if the annealing temperature is too high, quality defects such as thermal buckling, wrinkles and the like are easily generated in the continuous annealing furnace, and the normal passing of the steel plate in the continuous annealing furnace is seriously influenced.

Compared with the prior art, the invention can ensure that the plastic strain ratio is more than or equal to 1.7 r on the premise of ensuring that the yield strength of the steel strip is 180-240 MPa, the tensile strength is 340-400 MPa and the elongation is more than or equal to 36 percent₉₀The strain hardening index is more than or equal to 0.19 n₉₀(ii) a The secondary processing brittleness transition temperature is stabilized at minus 60 to minus 70 ℃, the cost can be reduced by not less than 5 percent compared with the prior art due to the reduction of the addition amount of Nb and Ti elements, and the secondary processing brittleness transition temperature is free from carbonized edges, and can be used for preparing the automobile outer covering piece applied in a more severe cold area.

Drawings

FIG. 1 is a metallographic structure diagram (total body) of a steel of the present invention;

FIG. 2 is a phase diagram showing the complex precipitates of FePTiNb in which a large amount of FePTiNb precipitates at grain boundaries during hot rolling according to the prior art.

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 in each example and comparative example of the present invention;

table 3 is a table of the performance tests and results of the examples and comparative examples of the present invention;

each example was produced according to the following procedure:

5) coiling, wherein the coiling temperature is controlled to be 640-680 ℃;

8) slowly cooling to 640-660 ℃ at a cooling speed of 6-11 ℃/s

9) Rapidly cooling to 440-460 ℃ at a cooling speed of 35-55 ℃/s;

TABLE 1 list of chemical compositions (wt%) of inventive and comparative examples

Description of the drawings: the values of Ti and Nb in table 1 were calculated by the formulae Ti = (48/14) N + (48/16) 1.5S + (48/12) 1.5C, and Nb = (93/12) C.

TABLE 2 List of the main process parameters of the examples of the invention and the comparative examples

TABLE 2

TABLE 3 Table of the results of mechanical Properties measurements of the examples of the invention and the comparative examples

As can be seen from Table 3, the ductile-brittle transition temperature of the steel plates with different finished product thicknesses is-60 to-70 ℃, and the steel plates have higher strength and better deep drawing performance. As can be seen from the comparative example, the ductile-brittle transition temperature of the comparative example reaches-30 ℃, and a large amount of FePTiNb composite precipitated phases are precipitated on grain boundaries during hot rolling mainly due to the addition of excessive Ti or Nb, and the precipitates are irregular in shape and different in size, so that the ductile-brittle transition temperature of the steel plate is seriously influenced.

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

Claims

1. A steel strip with excellent low-temperature secondary processing performance and tensile strength of 340MPa comprises the following components in percentage by weight: c: 0.0008 to 0.0028%, 0.07 to 0.10% of Si, Mn: 0.20-0.40%, P0.02-0.045%, S less than or equal to 0.008%, Al: 0.02-0.045%, Ti: 0.02-0.06%, Nb: 0.006-0.022%, B: 0.0003-0.001%, less than or equal to 0.002% of N, and the balance of Fe and inevitable impurities; and satisfies the following conditions: ti = (48/14) N + (48/16) 1.5S + (48/12) 1.5C, Nb = (93/12) C.

2. The steel strip of claim 1 having excellent secondary processability at low temperature and a tensile strength of 340MPa, wherein: the content of P is 0.025-0.04% by weight.

3. The steel strip of claim 1 having excellent secondary processability at low temperature and a tensile strength of 340MPa, wherein: the Mn content is 0.022-0.035% by weight.

4. The steel strip of claim 1 having excellent secondary processability at low temperature and a tensile strength of 340MPa, wherein: the weight percentage content of Ti is 0.030-0.050%.

5. The steel strip of claim 1 having excellent secondary processability at low temperature and a tensile strength of 340MPa, wherein: the Nb content is 0.010-0.018 wt%.

6. The method for producing a steel strip having a tensile strength of 340MPa grade excellent in secondary workability at low temperatures according to claim 1, comprising the steps of:

5) coiling, wherein the coiling temperature is controlled to be 640-680 ℃;

8) slowly cooling to 640-660 ℃ at a cooling speed of 6-11 ℃/s

9) Rapidly cooling to 440-460 ℃ at a cooling speed of 35-55 ℃/s;

7. The method of claim 6, wherein the steel strip with excellent secondary processability at low temperature and tensile strength of 340MPa is prepared by the following steps: the continuous annealing temperature is 815-822 ℃.