CN1878882A - Cold rolled steel sheet having aging resistance and superior formability, and process for producing the same - Google Patents

Abstract

A cold rolled steel sheet, and a method of manufacturing the same, designed to have aging resistance and excellent formability suitable for use in automobile bodies, electronic appliances, and the like. The cold rolled steel sheet comprises 0.003 % or less of C, 0.003 ~ 0.03 % of S, 0.01 ~ 0.1 % of Al, 0.02 % or less of N, 0.2 % or less of P, at least one of 0.03 ~ 0.2 % of Mn and 0.005 ~ 0.2 % of Cu, and a balance of Fe and other unavoidable impurities in terms of weight%. When the steel sheet comprises one of Mn and Cu, the composition of Mn, Cu, and S satisfies at least one relationship: 0.58*Mn/S < 10 and 1 << 0.5*Cu/S < 10, and when the steel sheet comprises both Mn and Cu, the composition of Mn, Cu, and S satisfies the relationship: Mn+Cu < 0.3 and 2 < 0.5*(Mn+Cu)/S << 20. Participates of MnS, CuS, and (Mn, Cu)S have an average size of 0.2 [mu]m or less. Since carbon content in a solid solution state in a crystal grain is controlled by fine precipitates of MnS, CuS, or (Mn, Cu)S, the steel sheet has enhanced aging resistance and formability, and has excellent yield strength and 15 strength-ductility.

Description

Cold Rolled Sheet Steel and production method thereof with resistance to deterioration and fabulous formability

Technical field

The present invention relates to mainly be applicable to the Cold Rolled Sheet Steel of body of a motor car, electronic apparatus etc.More specifically, the present invention relates to that resistance to deterioration and formability are able to improved Cold Rolled Sheet Steel by the threshold value of utilizing the carbon content of solid solution attitude in thin precipitation (fine precipitate) the control crystal grain, and the method for producing described Cold Rolled Sheet Steel.

Background technology

To being used for used Cold Rolled Sheet Steels such as body of a motor car, electronic apparatus,, require to have resistance to deterioration with high strength and formability thereof.Term " wears out " and is meant the strain aging phenomenon, and it can cause defective, is called as " tension strain ", and the sclerosis that takes place when it causes dislocation (to dislocation) by being fixed when the solid solution element such as C and N is caused.

Can give the Cold Rolled Sheet Steel resistance to deterioration by the batch annealing of aluminium killed steel.But batch annealing need prolong annealing time, has therefore reduced productivity, and has caused the serious variation of the mechanical properties that depends on the position on the steel sheet.Thereby, main no gap (IF) steel that uses, it is by adding reinforcement carbide or the nitride forming element such as Ti or Nb, producing by continuous annealing subsequently.

In order to produce the IF steel, the reinforcement that must add such as Ti or Nb forms carbide or nitride element.For this reason, because these elements may increase recrystallization temperature, so must at high temperature finish continuous annealing.Therefore, the method for this production IF steel cause productivity reduce, because big energy consumption makes production cost increase and serious environmental problem.And high temperature annealing causes various defectives usually, as crackle, distortion etc.

And, because Ti and Nb have the intensive oxidisability,, cause the steel-sheet surface imperfection so these elements produce a large amount of non-metallic inclusions.In addition, the IF steel crystal boundary that enbrittles, and therefore suffer so-called " secondary processing embrittlement ", this can cause the embrittlement of steel sheet after forming.In order to prevent this secondary processing embrittlement, added the element that comprises B.Simultaneously, when the IF steel is used for carrying out the product of surface treatment (as plating, coating and similar processing thereof), usually many defectives can take place on the surface of product.

In order to address these problems, proposed not contain the steel plate of Ti or Nb.As an example, Japanese Patent is openly announced (Hei) 6-093376,6-093377 and has disclosed the method for improving the steel-sheet resistance to deterioration by strictness control carbon content in 0.0001～0.0015wt% scope for 6-212354 number that the B that wherein adds 0.0001～0.003wt% scope replaces Ti or Nb.

According to these disclosures,, after steel plate annealing, need to quench to guarantee resistance to deterioration owing to can not guarantee resistance to deterioration fully.But, in this case, have a problem: because the shrend of quenching and normally in tank, carrying out, so on steel sheet, form zone of oxidation, and therefore follow the pickling of carrying out in order to remove zone of oxidation, thus the defective of surface of thin steel sheet caused, and this needs the additional production cost.And this steel sheet has than low strength.In addition, because steel sheet has relatively poor in-plane anisotropy, so produce gauffer and ear (ear) on steel sheet, this method needs bigger raw material consumption.

Simultaneously, the present inventor has proposed to produce the method for the Cold Rolled Sheet Steel with fabulous stretch forming and improved ductility under the situation that does not add Ti or Nb, be disclosed in Korean Patent and openly announce in 2000-0039137 number.This method comprises the steps: hot rolled plate steel material (steel ingot) and at Ar ₃Carry out finish rolling under transition temperature or the higher temperature in order to hot rolled steel sheet to be provided, described steel slab comprises (in wt%): 0.0005～0.002% C, 0.05～0.03% Mn, 0.015% or P still less, 0.01～0.08% Al; 0.001～0.005% N; And the Fe of equal amount (the balance of Fe) and other unavoidable impurities, wherein the component of C, N, S and P satisfies relation: C+N+S+P≤0.025%; Under 750 ℃ or lower temperature, make the steel sheet rolling; The steel sheet of (reduction rate) the cold rolling rolling of the rate of compression with 50～90% (wound); 650～850 ℃ temperature with 10 seconds of Cold Rolled Sheet Steel continuous annealing or the longer time.The Cold Rolled Sheet Steel of Sheng Chaning has fabulous ductility when guaranteeing resistance to deterioration by this method.But, according to the method that discloses, owing to must control C content, N content, S content and P content in Cold Rolled Sheet Steel, to satisfy following relationship: C+N+S+P≤0.025%, so be necessary in process of production to strengthen sweetening power and dephosphorizing capacity, thereby cause the problem of productivity and production cost aspect.Consider mechanical property, because the steel-sheet yield strength of final production is very low, so be necessary to use thicker material.In addition, after the processing, there are the following problems: because too high in-plane anisotropy index (Δ r) produces too much gauffer, and causes the steel-sheet fracture on steel sheet.

The present inventor has also proposed a kind of method of producing Cold Rolled Sheet Steel, and this method can improve the yield strength of the high tensile steel plate with 340MPa level tensile strength, and it is disclosed in Korean Patent and openly announces in 2002-0049667 number.This method comprises the steps: at Ar ₃Hot rolled plate steel material is in order to provide hot rolled steel sheet under texturing temperature or the higher temperature, and described steel slab comprises (in wt%): 0.0005～0.003% C, 0.1% or Mn still less, 0.003～0.02% S, 0.03～0.07% P, 0.01～0.1% Al; 0.005% or the Cu of N still less and 0.05～0.3%, wherein the atomic ratio of Cu/S is 2～10; With the cold rolling rolling steel sheet of 50～90% rate of compression; And under 700～880 ℃ temperature with 10 seconds to 5 of cold-rolled steel sheet continuous annealing minute.The Cold Rolled Sheet Steel of Sheng Chaning has the yield strength of the 240MPa of the raising in 340MPa level high-tensile steel plate by this method.But, because the steel-sheet ageing index is higher than 30MPa, so just can not guarantee this steel-sheet resistance to deterioration, and owing to the plastic anisotropy index (r of this steel sheet at 1.8 grades _m) time have 0.5 or bigger high in-plane anisotropy index (Δ r), and on steel sheet, produce too much gauffer, cause the steel-sheet fracture.

Simultaneously, Cold Rolled Sheet Steel known in the prior art, it is the high strength cold-rolled steel sheet with resistance to deterioration, and it is to produce by 0.3～0.7% Mn and Ti are joined the phosphorus content that improves simultaneously in the Carbon Steel Plate in the extra-low carbon steel plate.This Cold Rolled Sheet Steel has ductility-brittle transition temperature of 0～30 ℃; That is, Cold Rolled Sheet Steel has relatively poor secondary processing brittleness, and it is in the degree that will cause fracture to the impact under the room temperature.

Summary of the invention

Therefore, consider that the problems referred to above have just produced the present invention, and an object of the present invention is to provide a kind of Cold Rolled Sheet Steel that it has improved formability and resistance to deterioration under the situation that does not add Ti or Nb, and produces this steel-sheet method.

Another object of the present invention provides a kind of Cold Rolled Sheet Steel, it has fabulous yield strength, strength-ductility balanced characteristic, secondary processing embrittlement resistance and low degree anisotropy, have predetermined level or higher plasticity-anisotropic index simultaneously, and produce this steel-sheet method.

According to the present invention, by being provided, following Cold Rolled Sheet Steel can realize above-mentioned and other purposes, described Cold Rolled Sheet Steel comprises (in weight %): 0.003% or C still less; 0.003～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.03 at least a among～0.2% Mn and 0.005～0.2% the Cu; And the Fe of equal amount and other unavoidable impurities, wherein, when this steel sheet comprises Mn and Cu a kind of, the composition of Mn, Cu and S satisfies a kind of following relationship: 0.58*Mn/S≤10 and 1≤0.5*Cu/S≤10, and when steel sheet comprise Mn and Cu the two the time, the composition of Mn, Cu and S satisfies following relationship: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20, and wherein, MnS, CuS and (Mn, Cu) precipitation of S has 0.2 μ m or littler mean particle size.

Cold Rolled Sheet Steel of the present invention can be classified according at least a additive that is selected from the group that comprises Mn and Cu; That is, (1) singly adds the steel (do not comprise Cu, be also referred to as " MnS-precipitates steel ") of Mn, (2) steel that singly adds Cu (does not comprise Mn, be also referred to as " CuS-precipitates steel "), and the steel (being also referred to as " MnCu-precipitates steel ") of (3) adding Mn and Cu, will be described in detail below.

(1) MnS-precipitation ladle is drawn together (in weight %): 0.003% or C still less; 0.005～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.05～0.2% Mn; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn and S satisfies following relation: 0.58*Mn/S≤10, and the MnS precipitation has 0.2 μ m or littler mean particle size.The method of a kind of MnS of production precipitation steel comprises the steps: after with steel slab reheat to 1100 ℃ or higher temperature, hot rolled plate steel material and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature so that hot rolled steel sheet to be provided, described steel slab comprises (in wt%): 0.003% or C still less; 0.005～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.05～0.2% Mn; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn and S satisfies relation: 0.58*Mn/S≤10; With 200 ℃/min or faster speed cooling steel sheet; Under 700 ℃ or lower temperature, make refrigerative steel sheet rolling; The steel sheet of cold rolling rolling; And the cold rolling steel sheet of continuous annealing.

(2) CuS-precipitation ladle is drawn together (in weight %): 0.0005～0.003% C; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.01～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Cu and S satisfies relation: 1≤0.5*Cu/S≤10, and the precipitation of CuS has 0.1 μ m or littler mean particle size.The method of a kind of CuS of production precipitation steel comprises the steps: after with steel slab reheat to 1100 ℃ or higher temperature, hot rolled plate steel material and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature so that hot rolled steel sheet to be provided, described steel slab comprises (in wt%): 0.0005～0.003% C; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.01～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Cu and S satisfies relation: 1≤0.5*Cu/S≤10; Speed cooling steel sheet with 300 ℃/min; Under 700 ℃ or lower temperature, make refrigerative steel sheet rolling; The steel sheet of cold rolling rolling; And the cold rolling steel sheet of continuous annealing.

(3) MnCu-precipitation ladle is drawn together (in weight %): 0.0005～0.003% C; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.03～0.2% Mn; 0.005～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn, Cu and S satisfies following relationship: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20, and wherein, MnS, CuS and (Mn, Cu)/precipitation of S has 0.2 μ m or littler mean particle size.The method of a kind of MnCu-of production precipitation steel comprises the steps: after with steel slab reheat to 1100 ℃ or higher temperature, hot rolled plate steel material and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature so that hot rolled steel sheet to be provided, described steel slab comprises (in wt%): 0.0005～0.003% C; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.03～0.2% Mn; 0.005～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn, Cu and S satisfies following relationship: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20; Speed cooling steel sheet with 300 ℃/min; Under 700 ℃ or lower temperature, make refrigerative steel sheet rolling; The steel sheet of cold rolling rolling; And the cold rolling steel sheet of continuous annealing.

Above-mentioned Cold Rolled Sheet Steel is preferred for having the ductility Cold Rolled Sheet Steel of 240MPa level tensile strength or is used to have the 340MPa level or more high-tensile high strength cold-rolled steel sheet.

To being in the situation of the ductility Cold Rolled Sheet Steel in the 240MPa level, steel sheet comprises (in weight %): 0.003% or C still less; 0.003～0.03% S; 0.01～0.1% Al; 0.004% or N still less; 0.015% or P still less; At least a 0.03～0.2% Mn and 0.005～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, when steel sheet comprises Mn and Cu a kind of, the composition of Mn, Cu and S satisfies a kind of following relationship: 0.58*Mn/S≤10 and 1≤0.5*Cu/S≤10, and when steel sheet comprise Mn and Cu the two the time, the composition of Mn, Cu and S satisfies following relationship: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20, and wherein, MnS, CuS and (Mn, Cu) precipitation of S has 0.2 μ m or littler mean particle size.

To being in 340MPa or higher high strength cold-rolled steel-sheet situation, can be divided into wherein one or both steel that joins the ductility Cold Rolled Sheet Steel as P, Si and the Cr of solution strengthening element (solid solution-intensifyingelement), and the steel that wherein increases as the content of N in the ductility Cold Rolled Sheet Steel of precipitation strength element (precipitation-intensifying element).That is, wish in the ductility Cold Rolled Sheet Steel, to contain one or both 0.2% or P still less, 0.1～0.8% Si and 0.2～1.2% Cr.If separately P is joined in the ductility Cold Rolled Sheet Steel, so preferred P with 0.03～0.2% joins in the ductility Cold Rolled Sheet Steel.Alternatively, by N content being increased to 0.005～0.02% and add 0.03～0.06% P and can guarantee high-strength characteristic by the AlN precipitation mode.

In order further to improve the formability of Cold Rolled Sheet Steel, this steel sheet can further comprise 0.01～0.2% Mo, and in order to ensure resistance to deterioration, this steel sheet can further comprise 0.01～0.2% V.

Description of drawings

From below in conjunction with the detailed description that accompanying drawing carried out, will more be expressly understood above-mentioned and other purposes, characteristic and other advantages of the present invention, wherein:

Fig. 1 a has described the variation according to the precipitation granularity of the carbon content that is in the solid solution attitude in the crystal grain to the 1c diagram;

Fig. 2 a has described the sedimentary granularity according to the MnS of rate of cooling to the 2b diagram;

Fig. 3 a has described the sedimentary granularity according to the CuS of rate of cooling to the 3c diagram; And

MnS, CuS and (Mn, Cu) the sedimentary granularity of S according to rate of cooling described in Fig. 4 a and 4b diagram.

Embodiment

To describe the preferred embodiments of the present invention in detail now.But, be appreciated that the present invention is not limited to these embodiment.

Found the new fact in the process of the present inventor's raising steel-sheet resistance to deterioration under investigating the situation that does not add Ti and Nb, as described below.This fact is exactly MnS, CuS or (Mn, Cu) the thin precipitation of S can suitably be controlled the carbon content in the solid solution attitude in the crystal grain (that is, solid solution carbon (solidsolution carbon)), and helps to improve resistance to deterioration.These precipitations may produce positive influence to steel-sheet in-plane anisotropy index to the raising of the increase of yield strength, strength-ductility balanced characteristic and owing to precipitation strength.

As shown in Figure 1, as can be seen when MnS, CuS and (Mn, Cu) precipitation of S distributes when meticulousr, the content of solid solution carbon has reduced in the crystal grain.Because the solid solution carbon that is retained in the crystal grain moves freely relatively, so carbon moves and be coupling-connected to movably dislocation (dislocation), and influences the steel-sheet aging property.Therefore, when the content of solid solution carbon in the crystal grain is reduced to when being lower than predeterminated level, resistance to deterioration can be enhanced.Consider and guarantee resistance to deterioration, in the crystal grain content of solid solution carbon for the highest 20ppm or still less, and preferred 15ppm or still less.

Fig. 1 a is the diagram of following steel to 1c, and this ladle is drawn together 0.003% C, and can see as MnS, CuS and (Mn, when Cu) precipitation of S was distributed in 0.2 μ m or the littler granularity, the content of solid solution carbon preferably was controlled at 20ppm or still less in the crystal grain.Consider that the content that is used for controlling solid solution carbon in the crystal grain is in 15ppm or sedimentary granularity still less, as can be seen from Figure 1, only condition is that precipitation that the precipitation of MnS has about 0.2 μ m or littler granularity, a CuS has about 0.1 μ m or littler granularity and MnS, CuS and (Mn, Cu) precipitation of S has about 0.1 μ m or littler granularity.

Similarly, for the content of controlling solid solution carbon in the crystal grain at 20ppm or still less, be under 0.003wt% or the littler condition at the steel carbon containing, MnS, CuS and (Mn, Cu) precipitation of S is just extremely important subtly distribute.According to the present invention, have MnS, CuS and (Mn, Cu) under the thin sedimentary situation of S, carbon content preferably is increased to 0.003wt%, this can produce underload in the steel production process.

Notice the fact that these are new, investigated the MnS that distributes subtly, CuS and (Mn, Cu) the sedimentary method of S.The result shows the composition of these elements in the content of needs control Mn, Cu and S and the steel, and can obtain particulate by the rate of cooling after the control hot rolling.

Fig. 2 a is precipitating the diagram that is obtained after the granularity according to the rate of cooling after the steel sheet hot rolling is investigated, and this steel sheet comprises (in wt%): 0.0018% C; 0.15% Mn; 0.008% P; 0.015% S; 0.03% Al; And 0.0012% N (wherein 0.58*Mn/S=5.8).With reference to Fig. 2 a, can find to satisfy relation when the combination at Mn and S: under the condition of 0.58*Mn/S≤10, when suitably controlling the steel-sheet rate of cooling, the sedimentary granularity of MnS can be 0.2 μ m or littler.

Fig. 3 a is precipitating the diagram that is obtained after the granularity according to the rate of cooling after the steel sheet hot rolling is investigated, and this steel sheet comprises (in wt%): 0.0018% C; 0.01% P; 0.008% S; 0.05% Al; 0.0014% N; And 0.041% Cu (wherein 0.5*Cu/S=2.56).With reference to Fig. 3 a, can find to satisfy relation when the combination at Cu and S: under the condition of 1≤0.5*Cu/S≤10, when suitably controlling the steel-sheet rate of cooling, the sedimentary granularity of CuS can be 0.1 μ m or littler.

Fig. 4 a is precipitating the diagram that is obtained after the granularity according to the rate of cooling after the steel sheet hot rolling is investigated, and this steel sheet comprises (in wt%): 0.0025% C; 0.13% Mn; 0.009% P; 0.015% S; 0.04% Al; 0.0029% N; And 0.04% Cu (wherein Mn+Cu=0.17 and 0.5* (Mn+Cu)/S=5.67).With reference to Fig. 4 a, can find to satisfy relation: under the condition of Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20 when combination at Mn, Cu and S, suitably during control steel-sheet rate of cooling, MnS, CuS, (Mn, Cu) the sedimentary granularity of S can be 0.2 μ m or littler.

Cold Rolled Sheet Steel of the present invention has high-yield strength, and therefore allows steel sheet to reduce thickness, thereby its product is provided the influence of weight minimizing.And, because the low degree anisotropy, so when respectively at the processing steel sheet and after the processing steel sheet, just seldom produce gauffer and ear (ear).Below Cold Rolled Sheet Steel of the present invention and production method thereof are described in detail.

[Cold Rolled Sheet Steel of the present invention]

Carbon (C): carbon content is preferably 0.003wt% or still less.

If carbon content is higher than 0.003wt%, the amount of solid solution carbon increases in the crystal grain so, just is difficult to guarantee the resistance to deterioration of steel plate, and the crystallite size in the annealed sheet reduces, thereby significantly reduces the ductility of steel plate.More preferably, carbon content is 0.0005～0.003wt%.Carbon content can cause coarse grained generation in the hot-rolled sheet less than 0.0005wt%, thereby the intensity that reduces steel increases its in-plane anisotropy simultaneously.According to the present invention, owing to can reduce the amount of solid solution carbon in the steel, so carbon content rises to 0.003wt%.Therefore, can save the carbonization treatment that is used for finally reducing carbon content.For this reason, carbon content is preferably in the scope of 0.002wt%＜C≤0.003wt%.

Sulphur (S): sulphur content is preferably 0.003～0.03wt%.

Sulphur content be lower than 0.003wt% can cause not only reducing MnS, CuS, (Mn, amount Cu), and produce too much thick precipitation, thereby reduced the steel-sheet resistance to deterioration.Sulphur content is higher than 0.03wt% and can causes producing a large amount of solid solution sulphur, thereby has significantly reduced steel-sheet ductility and formability, and has increased hot-short possibility.According to the present invention, to the situation of MnS precipitation steel, sulphur content is preferably in the scope of 0.005wt%～0.03wt%.To the situation of CuS precipitation steel, sulphur content is preferably in the scope of 0.003wt%～0.025wt%.To the situation of MnCu precipitation steel, sulphur content is preferably in the scope of 0.003wt%～0.025wt%.

Aluminium (Al): aluminium content is preferably 0.01～0.1wt%.

Aluminium is the alloying element that is used as reductor usually.Yet in the present invention, adding aluminium is in order to stop in the steel by precipitating nitrogen by wearing out that solid solution nitrogen causes.Aluminium content is lower than 0.01wt% can cause a large amount of solid solution nitrogen, thus make must stop aging very difficult, otherwise aluminium content can cause a large amount of solid solution aluminium greater than 0.1wt%, thereby reduced steel-sheet ductility.According to the present invention, to the situation of CuS-precipitation steel and MnCu-precipitation steel, aluminium content is preferably in the scope of 0.01wt%～0.08wt%.If nitrogen content increases to 0.005～0.02%, can obtain high-strength steel sheet by the sedimentary strengthening effect of AlN so.

Nitrogen (N): nitrogen content is preferably 0.02wt% or still less.

Nitrogen is the inevitable element that adds in the steel production process in the steel, and in order to obtain to strengthen influence, the N that preferably adds in steel is to 0.02wt%.In order to obtain the ductility steel sheet, nitrogen content preferred 0.004% or still less.In order to obtain high-strength steel sheet, nitrogen content preferred 0.005～0.2%.Although influence nitrogen content and be necessary for 0.005% or bigger in order to obtain to strengthen, nitrogen content causes the reduction of steel-sheet formability greater than 0.02wt%.In order to utilize nitrogen that high-strength steel is provided, phosphorus content is preferably 0.03～0.06%.According to the present invention, guarantee high strength in order to precipitate by AlN, the combination of Al and N, that is, 0.52*Al/N (wherein Al and N represent with wt%) is preferably in 1～5 scope.The combination of Al and N (0.52*Al/N) can cause by solid solution nitrogen caused aging less than 1, and the combination of Al and N (0.52*Al/N) causes inappreciable reinforcement (strengthening) influence greater than 5.

Phosphorus (P): phosphorus content is preferably 0.2wt% or still less.

Phosphorus is alloying element, and it can increase a small amount of minimizing of solution strengthening influence and permission r-value (plasticity-anisotropic index), and can guarantee to have controlled the high strength of sedimentary steel plate.Therefore, in order to be used for guaranteeing high strength by making of P, P content is preferably 0.2wt% or lower.Phosphorus content can cause the reduction of steel sheet ductility greater than 0.2wt%.When adding phosphorus separately in steel in order to ensure the steel-sheet high strength, P content is preferably 0.03～0.2wt%.To the ductility steel sheet, P content is preferably 0.015wt% or lower.To being used for guaranteeing high-intensity steel sheet by sedimentary the making of AlN, P content is preferably 0.03～0.06wt%.This is owing to such fact: although 0.03wt% or bigger phosphorus content can be guaranteed target strength, phosphorus content can reduce the ductility and the formability of steel greater than 0.06wt%.According to the present invention, when having guaranteed the steel-sheet high strength, can suitably control to 0.2wt% or still less in order to obtain target strength P content by the mode that adds Si and Cr.

According to the present invention, preferably with at least a the joining in the steel in manganese (Mn) and the copper (Cu).These elements combine with S, produce MnS, CuS, (Mn, Cu) S precipitation.

Manganese (Mn): manganese content is preferably 0.03～0.2wt%.

Manganese is alloying element, and it can be used as MnS precipitation and solid solution sulphur in the precipitation steel, thereby stops by the caused red brittleness of solid solution sulphur.In the present invention, Mn combine with Mn for S and/or Cu and for the conditions suitable of rate of cooling under combine with Mn with thin MnS and/or (Mn because of S and/or Cu, Cu) the sedimentary form of S is precipitated, and Mn plays an important role in improving steel-sheet yield strength and in-plane anisotropy, guarantees the steel-sheet resistance to deterioration simultaneously substantially.In order to realize these influences, Mn content is necessary for 0.03wt% or bigger.Simultaneously, Mn content produces thick precipitation greater than 0.2wt%, thereby reduces the steel-sheet resistance to deterioration.If separately Mn is joined in the steel (that is, not adding Cu), manganese content is preferably 0.05～0.2wt% so.

Copper (Cu): copper content is preferably 0.005～0.2wt%.

Copper is alloying element, it produces thin precipitation under S and/or Mn and Cu bonded conditions suitable, and the rate of cooling before the rolling process of course of hot rolling, thereby the amount of solid solution carbon in the minimizing crystal grain, and in improving steel-sheet resistance to deterioration, in-plane anisotropy and plasticity-anisotropy, play an important role.In order to form thin precipitation, Cu content is necessary for 0.005wt% or bigger.If Cu content greater than 0.2wt%, can produce thick precipitation so, thereby reduce the steel-sheet resistance to deterioration.If separately Cu is added in the steel and (that is, do not add Mn), Cu content is preferably 0.01～0.2wt% so.

According to the present invention, the content of control Mn, Cu and S and combination (combination) are so that produce thin precipitation, and these add-ons according to Mn and Cu change.

Under the situation of MnS-precipitation steel, relation is preferably satisfied in the combination of Mn and S: 0.58*Mn/S≤10 (wherein Mn and S are in wt%).Mn combines with S and produces the MnS precipitation, and it can change sedimentary state according to the add-on of Mn and S, and therefore influences steel-sheet resistance to deterioration, yield strength and in-plane anisotropy index.0.58*Mn/S value greater than 10 produces thick MnS precipitation, causes ageing index to increase, thereby poor yield strength and plane anisotropic index is provided.

Under the situation of CuS-precipitation steel, relation is preferably satisfied in the combination of Cu and S: 1≤0.5*Cu/S≤10 (wherein Cu and S are in wt%).Cu combines with S and produces the CuS precipitation, and it can change sedimentary state according to the add-on of Cu and S, and therefore influences steel-sheet resistance to deterioration, plasticity-anisotropic index and in-plane anisotropy index.1 or bigger 0.5*Cu/S value make and produce effective CuS precipitation that the 0.58*Mn/S value greater than 10 produces thick CuS precipitation, causes the ageing index increase, and poor plasticity-anisotropic index and plane anisotropic index is provided.In order stably to guarantee 0.1 μ m or littler CuS precipitation, the value of 0.5*Cu/S is preferably 1～3.

When Mn and Cu join steel sheet together, the total content of Mn and Cu is preferably 0.3wt% or lower.This may generate thick precipitation owing to such fact: Mn and Cu content greater than 0.3%, and thereby makes and must guarantee that resistance to deterioration is very difficult.In addition, the value of 0.5* (Mn+Cu)/S (wherein Mn, Cu and S are in wt%) is preferably 2～20.Mn and Cu combine generation MnS, CuS with S and (it can change sedimentary state according to the add-on of Mn, Cu and S, and therefore influences resistance to deterioration, plasticity-anisotropic index and in-plane anisotropy index for Mn, Cu) S precipitation.Be 2 or the value of bigger 0.5* (Mn+Cu)/S can make and produce effectively precipitation, slightly precipitate and produce greater than 0.5* (Mn+Cu)/S value of 20, cause the increase of ageing index, thereby poor plasticity-anisotropic index and plane anisotropic index be provided.According to the present invention, when in the scope of value 2～20 of 0.5* (Mn+Cu)/S, sedimentary mean particle size is reduced to 0.2 μ m or littler.

In this case, wish that precipitation is with 2 * 10 ⁶Or bigger quantity distributes.When the value of 0.5* (Mn+Cu)/S since 7, sedimentary kind and sedimentary quantity generation noticeable change.Specifically, when the value of 0.5* (Mn+Cu)/S be 7 or more hour, many very thin MnS and CuS divide precipitation uniform distribution rather than (Mn, Cu) the S mixture precipitation of opening.Simultaneously, when the value of 0.5* (Mn+Cu)/S greater than 7 the time, do not consider to precipitate the less difference between the granularity, the sedimentary quantity that is distributed in crystal grain and the crystal boundary reduces, reason is (Mn, Cu) increase of the sedimentary amount of S mixture.In the present invention, the increase of precipitation quantity can improve resistance to deterioration, in-plane anisotropy index and anti-secondary processing embrittlement.For this reason, precipitation is preferably with 2 * 10 ⁸Or bigger quantity distributes.In the present invention, even under the identical situation of the value of 0.5* (Mn+Cu)/S, add a small amount of Mn and Cu and can reduce the sedimentary quantity that is distributed in crystal grain and the crystal boundary.If increase the content of Mn and Cu, precipitation meeting chap causes being distributed in the minimizing of the precipitation quantity in crystal grain and the crystal boundary so.

According to the present invention, MnS, CuS and (Mn, Cu) S precipitation preferably has 0.2 μ m or littler mean particle size.If MnS, CuS and (Mn, Cu) S precipitation has the mean particle size greater than 0.2 μ m, especially, ageing index increases rapidly, and plasticity-anisotropic index and in-plane anisotropy index become relatively poor.According to the present invention, the preferred size of MnS is 0.2 μ m or littler, and the preferred size of CuS is 0.1 μ m or littler.To when MnS, CuS and (Mn, Cu) S is deposited in the crystal grain mixed situation, sedimentary granularity is preferably 0.2 μ m or littler, and 0.1 μ m or littler more preferably.When sedimentary granularity reduced, it was preferred to consider resistance to deterioration.

According to the present invention, when being applied to 340MPa level or higher high-strength steel sheet, the solution strengthening element such as P can be joined steel sheet, that is, at least a P, Si and Cr can be joined steel sheet.Add the influence that phosphorus obtained and describe in front, so associated description is omitted.

Silicon (Si): silicone content is preferably 0.1～0.8%.

Si is an alloying element, and it can increase the solution strengthening influence makes ductility slightly reduce simultaneously, and therefore guarantees to control according to the present invention the high strength of sedimentary steel.0.1% or bigger Si content can guarantee steel-sheet intensity, but can cause the reduction of steel sheet ductility greater than 0.8% Si content.

Chromium (Cr): chromium content is preferably 0.2～1.2%.

Cr is an alloying element, and it can increase the solution strengthening influence and reduce secondary processing embrittlement temperature and ageing index by chromium carbide simultaneously, and therefore guarantees that the high strength of controlling sedimentary steel according to the present invention reduces the in-plane anisotropy index simultaneously.0.2% or bigger Cr content can guarantee steel-sheet intensity, but can cause the reduction of steel sheet ductility greater than 1.2% Cr content.

According to the present invention, preferably molybdenum (Mo) and/or vanadium (V) are joined Cold Rolled Sheet Steel.

Molybdenum (Mo): molybdenum content is preferably 0.01～0.2%.

Mo is an alloying element, and it can increase steel-sheet plasticity-anisotropic index.0.01% or bigger Mo content can increase plasticity-anisotropic index, but can cause red brittleness and no longer increase plasticity-anisotropic index greater than 0.2% Mo content.

Vanadium (V): content of vanadium is preferably 0.01～0.2%.

V is an alloying element, and it can guarantee resistance to deterioration by precipitation solid solution C.0.01% or bigger V content can increase resistance to deterioration, but can reduce plasticity-anisotropic index greater than 0.2% V content.The composition of V and C (0.25*V/C) preferably satisfies relation: 1≤0.25*V/C≤20 (wherein V and C represent with wt%).The composition of V and C (0.25*V/C) is less than the precipitating action of 1 meeting reduction solid solution C, and the composition of V and C (0.25*V/C) can reduce plasticity-anisotropic indexs greater than 20.

[producing the method for Cold Rolled Sheet Steel]

The invention is characterized in the steel sheet that satisfies above-mentioned composition by hot rolling and cold rolling the processing, thereby allow to reduce sedimentary mean particle size on the Cold Rolled Sheet Steel.Sedimentary mean particle size is subjected to the content of Mn, Cu and S and the influence of composition and production process, and especially is subjected to directly influencing of hot rolling postcooling speed.

[hot-rolled condition]

According to the present invention, the steel that satisfies above-mentioned composition is carried out reheat, carry out hot rolling then and handle.The reheat temperature is preferably 1100 ℃ or higher.When with the steel reheat to the temperature that is lower than 1100 ℃, because the thick precipitation that produces in the continuous casting process is because low reheat temperature keeps incomplete dissolved state, so remain thick precipitation in follow-up continuing of hot rolling.

Preferably, with Ar ₃Transition temperature or higher temperature carry out carrying out hot rolling under the condition of finish rolling.This is owing to such fact: be lower than Ar ₃The finish rolling that transition temperature carries out produces rolling particle, thereby significantly reduces steel-sheet ductility and formability.

Rate of cooling after the hot rolling is preferably 200 ℃/min or bigger.More specifically, between the rate of cooling of the sedimentary steel of (1) MnS-, the sedimentary steel of (2) CuS-and the sedimentary steel of (3) MnCu-, there is small difference.

At first, (1) under the situation of the sedimentary steel of MnS-, rate of cooling is preferably 200 ℃/min or bigger.Even when the composition of Mn and S according to the present invention satisfied relation: 0.58*Mn/S≤10, the rate of cooling that is lower than 200 ℃/min can produce the thick MnS precipitation that has greater than the granularity of 0.2 μ m.This is owing to such fact: when rate of cooling increased, a large amount of nuclears produced, and made the MnS precipitation attenuate.When the composition of Mn and S satisfies relation: 0.58*Mn/S＞10, the thick sedimentary quantity that is in incomplete dissolved state in the reheat treating processes increases, even make the increase rate of cooling, the quantity of nuclear can not increase yet, and therefore MnS precipitates can not become thinner (Fig. 2 b, 0.024% C; 0.43% Mn; 0.011% P; 0.009% S; 0.035% Al; And 0.0043% N (in wt%)).

With reference to Fig. 2 a and 2b, because the increase of rate of cooling causes the sedimentary generation of thinner MnS, so unnecessary to the rate of cooling proposition upper limit.But, even when rate of cooling be 1000 ℃/min or bigger because the sedimentary granularity of MnS can further not reduce, so rate of cooling 200～1000 ℃/min more preferably.

Secondly, (2) under the situation of the sedimentary steel of CuS-, hot rolling postcooling speed is preferably 300 ℃/min or bigger.Even when the composition of Cu and S according to the present invention satisfied relation: 0.5*Cu/S≤10, the rate of cooling that is lower than 300 ℃/min can produce the thick CuS precipitation that has greater than the granularity of 0.1 μ m.This is owing to such fact: when rate of cooling increased, a large amount of nuclears produced, and made the CuS precipitation attenuate.When the composition of Cu and S satisfies relation: 0.5*Cu/S＞10, the thick sedimentary quantity that is in incomplete dissolved state in the reheat treating processes increases, even make the increase rate of cooling, the quantity of nuclear can not increase yet, and therefore CuS precipitates can not become thinner (Fig. 3 c, 0.0019% C; 0.01% P; 0.005% S; 0.03% Al; 0.0015% N; And 0.28% Cu (in wt%)).

With reference to Fig. 3 a to 3c, because the increase of rate of cooling causes the sedimentary generation of thinner CuS, so the unnecessary upper limit that rate of cooling is provided.But, even when rate of cooling be 1000 ℃/min or bigger because the sedimentary granularity of CuS can further not reduce, so rate of cooling 300～1000 ℃/min more preferably.Fig. 3 a and 3b (0.0018% C; 0.01% P; 0.005% S; 0.03% Al; 0.0024% N; And 0.081% Cu (in wt%)) shows the situation of 0.5*Cu/S≤3 and 0.5*Cu/S＞3 respectively.With reference to accompanying drawing, as can be seen when the value of 0.5*Cu/S be 3 or more hour, can more stably obtain to have the 0.1 μ m or the CuS precipitation of small grain size more.

Once more, (3) under the situation of the sedimentary steel of MnCu-, hot rolling postcooling speed is preferably 300 ℃/min or bigger.Even when the composition of Mn, Cu and S according to the present invention satisfies relation: during 2≤0.5* (Mn+Cu)/S≤20, the rate of cooling that is lower than 300 ℃/min can produce the thick precipitation that has greater than the mean particle size of 0.2 μ m.This is owing to such fact: when rate of cooling increased, a large amount of nuclears produced, and made precipitation attenuate.When the composition of Mn and S satisfies relation: during 0.5* (Mn+Cu)/S＞20, the thick precipitation that is in incomplete dissolved state in the reheat process increases, even make the increase rate of cooling, the quantity of nuclear can not increase yet, and therefore can not become thinner (Fig. 4 b, 0.0025% C of precipitation; 0.4% Mn; 0.01% P; 0.01% S; 0.05% Al; 0.0016% N; And 0.15% Cu (in wt%)).

With reference to Fig. 4 a and 4b, because the increase of rate of cooling causes thinner sedimentary generation, so unnecessary to the rate of cooling proposition upper limit.But, even when rate of cooling be 1000 ℃/min or bigger because sedimentary granularity can further not reduce, so rate of cooling 300～1000 ℃/min or bigger more preferably.

[condition of curling]

After above-mentioned hot rolling is handled, preferably carry out rolling and handle 700 ℃ or lower temperature.When carrying out the rolling processing in the temperature that is higher than 700 ℃, the precipitation of formation is too thick, therefore can reduce the resistance to deterioration of steel.

[cold rolling condition]

With cold-rolling of steel plate to the thickness of wishing, preferably in 50～90% rate of compression (reductionrate).Because rate of compression can cause producing a small amount of nuclear less than 50% behind full annealed, annealing back excessive grain row becomes, to such an extent as to produce the coarse particles by annealing recrystallization, therefore reduces steel-sheet intensity and formability.The shrinkage of colding pressing can cause the formability that improves greater than 90%, produces excessive nuclear simultaneously, to such an extent as to that the particle by annealing recrystallization becomes is meticulous, therefore reduces the ductility of steel.

[continuous annealing]

The continuous annealing temperature plays an important role on definite mechanical performance of products.According to the present invention, preferably carry out continuous annealing 500～900 ℃ temperature.The continuous annealing temperature is lower than 500 ℃ can produce meticulous recrystallization grains, to such an extent as to the ductility that can not obtain to wish.The continuous annealing temperature is higher than 900 ℃ can produce thick recrystallization grains, so that reduce the intensity of steel.Keep the hold-time of continuous annealing so that finish the recrystallization of steel, and the recrystallization of steel can be after continuous annealing be finished in about 10 seconds or longer time.

With reference to following embodiment the present invention is described in more detail.

Among the embodiment that is described below, according to ASTM standard (ASTM E-8 standard) steel plate is processed into standard model, and its mechanical property is detected.Utilize tensile strength test machine (can obtain model 6025 from INSTRON company) that yield strength, tensile strength, elongation, plasticity-anisotropic index (r-value), in-plane anisotropy index (Δ r value) and ageing index (AI) are detected.In these embodiments, by following equation: r-value (r _m=(r ₀+ 2r ₄₅+ r ₉₀)/4 and Δ r=(r ₀-2r ₄₅+ r ₉₀)/2) plasticity-anisotropic index (r-value) and plane anisotropic index (Δ r value) have been obtained.

In addition, in order to obtain to be distributed in sedimentary mean particle size and the quantity in the sample, all sedimentary granularities and the quantity that exists in the material is detected.

The sedimentary steel of [embodiment 1-1] MnS-

In order to obtain the sedimentary steel of MnS-according to the present invention, after temperature, then steel slab is carried out finish rolling, so that hot rolled steel sheet to be provided with the steel slab reheat to 1200 shown in the table 1 ℃, hot rolled steel sheet is cooled off with the speed of 200 ℃/min, and 650 ℃ of rolling.Then, hot rolled steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.Exceptionally, the sample A8 in the table 1 behind reheat to 1050 ℃, then carries out finish rolling, with the speed cooling sample of 50 ℃/min, and then at 750 ℃ of coilings.

Table 1

Sample number	Component (wt%)
											C	Mn	P	S	Al	N	Mo	V	R-1	R-2
	≤0.003	0.05- 0.2	≤0.015	0.005- 0.03	0.01- 0.1	≤0.004	0.01- 0.2	0.01- 0.2	≤10	1- 20
											A1	0.0023	0.08	0.01	0.005	0.04	0.0015	-	-	9.28
A2	0.0018	0.10	0.011	0.012	0.05	0.0026	-	-	4.83
A3	0.0018	0.15	0.008	0.015	0.03	0.0012	-	-	5.8
											A4	0.0027	0.09	0.012	0.025	0.035	0.0018	-	-	2.09
A5	0.0026	0.4	0.009	0.01	0.02	0.0039	-	-	23.2
											A6	0.0038	0.10	0.011	0.008	0.05	0.0038	-	-	7.25
A7	0.0015	0.35	0.01	0.032	0.03	0.0015	-	-	6.34
											A8	0.0023	0.08	0.01	0.008	0.04	0.0015	-	-	5.8
A9	0.0013	0.09	0.01	0.008	0.033	0.025	0.03	-	6.53
											A10	0.0022	0.15	0.012	0.011	0.025	0.0022	0.053	-	7.91
A11	0.0015	0.10	0.008	0.015	0.043	0.0023	0.074	-	3.87
											A12	0.0025	0.1	0.009	0.021	0.034	0.0028	0.11	-	2.76
A13	0.0022	0.12	0.009	0.014	0.03	0.0021	0.15	-	4.97
											A14	0.0022	0.4	0.009	0.009	0.032	0.0033	0.25	-	25.8
A15	0.0015	0.1	0.011	0.009	0.033	0.0025	-	0.023	6.44	3.83
											A16	0.0024	0.08	0.01	0.01	0.035	0.0012	-	0.051	4.64	5.13
A17	0.0025	0.12	0.008	0.012	0.023	0.0015	-	0.08	5.8	8
											A18	0.0015	0.11	0.01	0.02	0.032	0.002	-	0.11	3.19	18.3

A19	0.0027	0.08	0.008	0.01	0.033	0.0011	-	0.154	4.64	14.3
											A20	0.002	0.4	0.01	0.013	0.022	0.0013	-	0.325	17.8	30
A21	0.0023	0.11	0.011	0.011	0.023	0.0017	0.017	0.025	5.8	2.72
											A22	0.0027	0.09	0.01	0.009	0.037	0.0027	0.074	0.082	5.8	7.59
A23	0.0025	0.08	0.009	0.012	0.032	0.0031	0.15	0.16	3.87	16

Annotate: R-1=0.58*Mn/S, R-2=0.25*V/C

Table 2

Sample number	Mechanical property						AS (μm)	Remarks
									YP (Mpa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)
	A1	211	309	49	1.83	0.28									23	0.05	IS
A2							209	311	52	1.93	0.34	22	0.12	IS
	A3	201	295	54	1.94	0.31									21	0.15	IS
A4							223	319	48	1.88	0.23	27	0.14	IS
	A5	211	312	48	1.93	0.52									34	0.62	CS
A6							254	329	45	1.57	0.41	49	0.09	CS
	A7	222	316	48	1.82	0.58									38	0.46	CS
A8
		200	291	53	1.69	0.48	37	0.34	CS
A9										213	311	50	2.24	0.31	15	0.06	IS
	A10	209	307	53	2.15	0.25	25	0.11	IS
A11										219	318	49	2.34	0.28	16	0.12	IS
	A12	220	321	49	2.25	0.24	26	0.13	IS
A13										234	328	49	2.20	0.31	24	0.14	IS
	A14	241	333	47	2.01	0.43	42	0.54	CS
A15										175	295	50	1.82	0.26	0	0.06	IS
	A16	163	301	53	1.86	0.21	0	0.11	IS
A17										158	284	49	1.9	0.19	0	0.12	IS
	A18	148	278	49	1.77	0.17	0	0.13	IS
A19										175	302	49	1.74	0.18	0	0.14	IS
	A20	182	308	47	1.52	0.21	0	0.54	CS
A21										158	290	50	2.19	0.35	0	0.07	IS
	A22	162	288	49	2.22	0.39	0	0.08	IS
A23										172	292	49	2.08	0.29	0	0.11	IS

Annotate: YP=yield strength, TS=tensile strength, El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, the sedimentary mean particle size of AS=, IS=steel of the present invention, CS=compared steel.

As shown in table 2, steel of the present invention not only has high anti-ageing, and has high-yield strength and fabulous formability.

Simultaneously, to have 23.2 0.58*Mn/S, mean particle size be the thick precipitation of 0.62 μ m and the ageing index that causes the 34MPa of relatively poor resistance to deterioration to sample A5.Therefore sample A6 has high-load carbon, and has too high and also can cause the ageing index of the 49MPa of relatively poor resistance to deterioration.Sample A7 has 6.34 0.58*Mn/S, and it within the scope of the invention.But Mn that this sample has and the content of S have departed from scope of the present invention, and produce thick MnS precipitation, thereby the ageing index of 38MPa is provided.Therefore, in sample A7, can not guarantee resistance to deterioration, and the steel-sheet formability is relatively poor.Exceptionally, under the situation of sample A8, because recrystallization temperature is 1050 ℃, this temperature is low excessively, can not dissolve fully so precipitate in the reheat process, produces too much precipitation, it not exclusively dissolves, and because the rolling temperature is too high, so precipitation is that mean particle size is the thick precipitation of 0.34 μ m, to such an extent as to be difficult to guarantee resistance to deterioration.

[embodiment 1-2] has the sedimentary steel of high strength CuS-of solution strengthening

In order to obtain the sedimentary steel of high strength CuS-according to the present invention, after the temperature with the steel slab reheat to 1200 shown in the table 3 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the speed cooling steel sheet of 200 ℃/min, and 650 ℃ of rolling.Then, then hot rolled steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.

Table 3

Sample number	Component (wt%)
													C	Mn	P	Si	Cr	S	Al	N	Mo	V	R-1	R-2
	≤0.003	0.05- 0.2	≤0.2	0.1- 0.8	0.2- 1.2	0.005- 0.03	0.01- 0.1	≤0.004	0.01- 0.2	0.01- 0.2	≤10	1- 20
													B1	0.0023	0.08	0.052	-	-	0.006	0.04	0.0015	-	-	7.73
B2	0.0018	0.10	0.102	-	-	0.010	0.05	0.0026	-	-	5.8
													B3	0.0025	0.08	0.151	-	-	0.012	0.035	0.0018	-	-	3.87
B4	0.0022	0.4	0.109	-	-	0.011	0.05	0.0038	-	-	21.1
													B5	0.0024	0.4	0.07	-	-	0.01	0.04	0.0016	Ti：0.05	-
B6	0.0019	0.11	0.01	0.22	-	0.008	0.04	0.0012	-	-	7.78
													B7	0.0018	0.1	0.011	0.62	-	0.009	0.035	0.0025	-	-	6.4
B8	0.0026	0.42	0.01	0.25	-	0.01	0.03	0.0028	-	-	24.4
													B9	0.0024	0.09	0.01	-	0.32	0.007	0.05	0.0012	-	-	7.46
B10	0.0022	0.11	0.015	-	0.63	0.012	0.04	0.0028	-	-	5.31
													B11	0.0018	0.11	0.011	-	0.95	0.015	0.03	0.0022	-	-	4.25
B12	0.0017	0.1	0.048	-	-	0.01	0.034	0.0025	0.025	-	5.8
													B13	0.002	0.09	0.011	0.21	-	0.01	0.024	0.0018	0.02	-	5.22
B14	0.0014	0.1	0.011	-	0.3	0.008	0.03	0.0032	0.025	-	7.25
													B15	0.002	0.09	0.048	0.21	0.3	0.012	0.033	0.0022	0.1	-	4.35
B16	0.0018	0.11	0.05	-	-	0.011	0.03	0.002	-	0.02	5.8	2.78
													B17	0.0022	0.11	0.01	0.25	-	0.009	0.034	0.0022	-	0.021	7.08	2.39
B18	0.0015	0.11	0.01	-	0.33	0.01	0.023	0.0022	-	0.02	6.38	3.33
													B19	0.0023	0.09	0.054	-	-	0.01	0.043	0.0029	0.021	0.017	5.22	1.85
B20	0.0026	0.09	0.012	0.26	-	0.011	0.024	0.0019	0.019	0.016	4.75	1.54
													B21	0.0025	0.11	0.01	-	0.33	0.01	0.023	0.0022	0.017	0.021	6.38	2.1

Annotate: R-1=0.58*Mn/S, R-2=0.25*V/C

Table 4

Sample number	Mechanical property							AS (μm)	Remarks
										YP (MPa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBTT (℃)
	B1	241	356	47	1.83	0.31	28										-70	0.11	IS
B2								299	402	42	1.65	0.32	23	-50	0.09	IS
	B3	352	456	35	1.53	0.31	27										-40	0.14	IS
B4								289	394	39	1.63	0.58	45	-60	0.73	CS
	B5	210	353	40	1.73	0.58	0										+0	-	CVS
B6								241	356	50	1.75	0.28	24	-80	0.11	IS
	B7	352	456	38	1.47	0.31	22										-50	0.14	IS
B8								231	346	45	1.72	0.58	42	-70	0.49	CS
	B9	235	352	47	1.70	0.20	21										-80	0.08	IS
B10								299	418	44	1.51	0.19	18	-60	0.07	IS
	B11	349	459	36	1.42	0.23	16										-50	0.11	IS
B12								238	359	46	2.09	0.3	18	-80	0.13	IS
	B13	238	362	48	2.09	0.32	22										-80	0.11	IS
B14								228	358	48	2.17	0.25	15	-80	0.1	IS
	B15	350	470	35	1.61	0.15	19										-60	0.1	IS
B16								203	355	44	1.76	0.23	0	-70	0.12	IS
	B17	198	360	47	1.77	0.32	0										-70	0.13	IS
B18								197	352	47	1.65	0.28	0	-80	0.11	IS
	B19	205	356	44	2.01	0.31	0										-60	0.11	IS
B20								198	360	47	1.77	0.27	0	-70	0.13	IS
	B21	201	350	48	1.98	0.28	0										-70	0.07	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, the AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, IS=steel of the present invention, the CS=compared steel, the CVS=conventional steel.

As shown in table 3, sample B1～B3 and B6 and B7 have 240MPa or higher yield strength, 35% or bigger elongation and 11,3000 yield strength-ductility balanced (yield strength * ductility).Steel of the present invention has fabulous formability and 30MPa or lower ageing index, to such an extent as to can guarantee resistance to deterioration.In addition, steel of the present invention has-40 ℃ or lower ductility-brittle transition temperature and fabulous secondary processing brittleness.

Sample B5 (conventional steel) is high strength cold-rolled steel sheet, and has fabulous ageing index.But, because high ductibility-brittle transition temperature, so there is high fracture possibility, even to the impact under the room temperature.

[embodiment 1-3] uses the sedimentary steel of MnS-of AlN precipitation strength

After the temperature with the steel slab reheat to 1200 shown in the table 5 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the speed cooling steel sheet of 200 ℃/min, and 650 ℃ of rolling.Then, then hot rolled steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.

Table 5

Sample number	Component (wt%)
												C	Mn	P	S	Al	N	Mo	V	R-1	R-3	R-2
	≤0.003	0.05- 0.2	0.03- 0.06	0.005- 0.03	0.01- 0.1	0.005- 0.02	0.01- 02	0.01- 0.2	≤10	1-5	1- 20
												C1	0.0019	0.1	0.04	0.008	0.042	0.015			6.5	1.46
C2	0.0028	0.09	0.042	0.007	0.04	0.0068			7.73	3.06
												C3	0.0023	0.11	0.04	0.010	0.05	0.0082			5.8	3.17
C4	0.0018	0.08	0.043	0.009	0.055	0.0065			3.87	4.4

C5	0.0022	0.09	0.04	0.011	0.008	0.0067			6.53	0.46
												C6	0.0019	0.4	0.04	0.009	0.04	0.0083			25.8	2.51
C7	0.0015	0.11	0.042	0.01	0.055	0.012	0.028		6.38	2.25
												C8	0.0012	0.1	0.04	0.008	0.033	0.011		0.018	7.25	1.56	3.75
C9	0.0023	0.11	0.043	0.008	0.053	0.011	0.022	0.017	7.98	2.51	1.85

Annotate: R-1=0.58*Mn/S, R-2=0.25*V/C, R-3=0.52*Al/N

Table 6

Sample number	Mechanical property							AS (μm)	Remarks
										YP (MPa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBT T (℃)
	C1	231	352	46	1.78	0.31	22										-70	0.07	IS
C2								229	344	48	1.82	0.38	25	-70	0.09	IS
	C3	235	348	48	1.83	0.31	22										-70	0.09	IS
C4								231	346	48	1.82	0.32	25	-70	0.07	IS
	C5	218	332	42	1.62	0.34	49										-70	0.12	CS
C6								221	328	46	1.72	0.54	38	-70	0.38	CS
	C7	225	355	47	2.15	0.31	12										-80	0.08	IS
C8								195	354	47	1.76	0.29	0	-70	0.09	IS
	C9	198	350	48	1.99	0.29	0										-70	0.1	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, IS=steel of the present invention, CS=compared steel.

The sedimentary steel of [embodiment 2-1] CuS-

After the temperature with the steel slab reheat to 1200 shown in the table 7 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 400 ℃/min, and 650 ℃ of rolling.Then, then hot rolled steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.Exceptionally, in table 7 under the situation of sample D8, after being reheated 1050 ℃ temperature, then carry out finish rolling, with the speed cooling sample of 400 ℃/min, and then 650 ℃ of rolling.In addition, under the situation of sample D14～D17, after being reheated 1250 ℃ temperature, then carry out finish rolling, with the speed cooling sample of 550 ℃/min, and then 650 ℃ of rolling.

Table 7

Sample number	Component (wt%)
											C	P	S	Al	N	Cu	Mo	V	R-4	R-2
	≤0.003	≤0.015	0.003- 0.025	0.01- 0.1	≤0.004	0.01- 0.2	001- 0.2	0.01- 0.2	1- 10	1- 20
											D1	0.0017	0.007	0.008	004	0.0028	0.035			2.19
D2	0.0018	0.010	0.008	0.05	0.0014	0.041			2.56
											D3	0.0016	0.012	0.015	0.03	0.0012	0.083			2.77
D4	0.0025	0.009	0.005	0.02	0.0039	0.021			2.1
											D5	0.0018	0.01	0.005	0.03	0.0024	0.081			8.1
D6	0.0022	0.011	0.012	0.05	0.0038	0.005			0.21
											D7	0.0019	0.01	0.005	0.03	0.0015	0.28			28
D8	0.0018	0.010	0.008	0.05	0.0014	0.041			2.56
											D9	0.0015	0.01	0.01	0.035	0.0022	0.038	0.015		1.9
D10	0.0028	0.011	0.008	0.025	0.0021	0.045	0.05		2.81
											D11	0.0018	0.009	0.012	0.033	0.0032	0.084	0.11		3.5
D12	0.0024	0.01	0.009	0.042	0.0029	0.031	0.17		1.72
											D13	0.0028	0.011	0.012	0.035	0.0024	0.035	0.28		1.46
D14	0.0018	0.009	0.011	0.025	0.0026	0.03		0.025	1.36	3.47
											D15	0.002	0.012	0.009	0.022	0.0011	0.052		0.075	2.89	9.38
D16	0.0026	0.011	0.008	0.028	0.0038	0.084		0.17	3.82	16.3

D17	0.002	0.012	0.01	0.039	0.0044	0.065		0.28	3.25	35
											D18	0.0016	0.011	0.009	0.035	0.0037	0.043	0.021	0.017	2.39	2.66
D19	0.0022	0.01	0.01	0.042	0.0024	0.058	0.075	0.082	2.9	9.32
											D20	0.0027	0.01	0.011	0.022	0.0022	0.064	0.17	0.15	5.82	13.9

Annotate: R-2=0.25*V/C, R-4=0.5*Cu/S

Table 8

Sample number	Mechanical property						AS (μm)	Remarks
									YP (Mpa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)
	D1	206	298	53	2.15	0.29									21	0.08	IS
D2							189	312	52	2.33	0.38	18	0.05	IS
	D3	223	321	50	2.29	0.29									21	0.05	IS
D4							197	319	53	2.23	0.35	28	0.07	IS
	D5	218	316	52	2.18	0.25									29	0.09	IS
D6							189	296	54	2.58	0.79	46	-	CS
	D7	209	309	46	1.87	0.53									51	0.34	CS
D8							173	275	58	2.62	1.09	49	0.49	CS
	D9	193	300	53	2.58	0.32									19	0.09	IS
D10							211	310	52	2.63	0.35	25	0.07	IS
	D11	202	301	50	2.49	0.28									20	0.07	IS
D12							207	312	52	2.53	0.33	23	0.07	IS
	D13	215	326	48	2.28	0.51									29	0.19	CS
D14							173	289	53	2.16	0.24	0	0.1	IS
	D15	183	293	52	2.23	0.32									0	0.09	IS
D16							185	295	50	2.19	0.19	0	0.08	IS
	D17	179	301	48	1.73	0.19									0	0.1	CS
D18							166	285	53	2.45	0.41	0	0.09	IS
	D19	169	290	52	2.53	0.4									0	0.1	IS
D20							171	305	50	2.49	0.46	0	0.08	IS

Annotate: YP=yield strength, TS=tensile strength, El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, the sedimentary mean particle size of AS=, IS=steel of the present invention, CS=compared steel.

[embodiment 2-2] uses the sedimentary steel of high strength CuS-of solution strengthening

After the temperature with the steel slab reheat to 1200 shown in the table 9 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 400 ℃/min, and 650 ℃ of rolling.Then, then the rolling steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.

Table 9

Sample number	Component (wt%)
													C	P	Si	Cr	S	Al	N	Cu	Mo	V	R-4	R-2
	≤0.003	≤0.2	0.1- 0.8	0.2- 1.2	0.003- 0.025	0.01- 0.1	≤0.004	0.01- 0.2	0.01- 0.2	0.01- 0.2	1- 10	1- 20
													E1	0.0021	0.045			0.015	0.04	0.0018	0.045			1.5
E2	0.0015	0.048			0.013	0.03	0.0023	0.06			2.25
													E3	0.0021	0.1			0.011	0.04	0.0015	0.056			2.55
E4	0.0025	0.11			0.011	0.04	0.0038	0.106			4.82
													E5	0.0018	0.16			0.008	0.05	0.0012	0.141			8.81
E6	0.0018	0.05			0.01	0.02	0.0039	0.005			0.25
													E7	0.0022	0.109			0.011	0.05	0.0038	0.32			14.5
E8	0.0022	0.01	0.23		0.015	0.04	0.0014	0.045			1.5
													E9	0.0024	0.009	0.21		0.012	0.05	0.0024	0.052			2.15
E10	0.0025	0.01	0.4		0.008	0.04	0.0018	0.045			2.81
													E11	0.0015	0.012	0.43		0.01	0.04	0.0032	0.087			4.34
E12	0.0021	0.010	0.63		0.008	0.035	0.0012	0.141			8.81
													E13	0.0026	0.01	0.25		0.01	0.03	0.0028	0.004			0.2

E14	0.0017	0.012	0.41		0.005	0.04	0.0032	0.221			22.1
													E15	0.0024	0.01		0.30	0.012	0.04	0.0022	0.043			1.8
E16	0.0021	0.012		0.33	0.01	0.04	0.0018	0.05			2.5
													E17	0.0024	0.009		0.60	0.009	0.05	0.0032	0.05			2.78
E18	0.0024	0.013		0.63	0.009	0.04	0.0028	0.078			4.33
													E19	0.0016	0.009		0.95	0.005	0.04	0.0032	0.083			8.3
E20	0.0026	0.011		0.35	0.012	0.04	0.0028	0.008			0.33
													E21	0.0025	0.009		0.61	0.011	0.05	0.0023	0.252			14
E22	0.0025	0.052			0.012	0.023	0.0033	0.054	0.035		2.25
													E23	0.0014	0.01	0.23		0.009	0.035	0.0034	0.05	0.022		2.78
E24	0.0014	0.011		0.33	0.01	0.034	0.0024	0.04	0.018		2
													E25	0.0015	0.055			0.01	0.043	0.0023	0.052		0.023	2.6	3.83
E26	0.0012	0.009	0.25		0.011	0.023	0.0014	0.055		0.024	2.5	5
													E27	0.0012	0.01		0.35	0.009	0.034	0.0025	0.042		0.017	2.33	3.54
E28	0.0024	0.054			0.012	0.034	0.0023	0.05	0.018	0.02	2.08	2.08
													E29	0.0017	0.01	0.26		0.01	0.032	0.0024	0.05	0.022	0.018	2.5	2.65
E30	0.0023	0.011		0.34	0.01	0.024	0.0024	0.046	0.021	0.018	2.3	1.96

Annotate: R-2=0.25*V/C, R-4=0.5*Cu/S

Table 10

Sample number	Mechanical property							AS (μm)	Remarks
										YP (MPa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBTT (℃)
	E1	265	360	49	1.85	0.24	25										-70	0.05	IS
E2								271	365	49	1.83	0.25	22	-70	0.05	IS
	E3	301	410	41	1.73	0.24	21										-50	0.06	IS
E4								299	402	42	1.69	0.22	27	-50	0.06	IS
	E5	352	456	35	1.53	0.18	21										-40	0.09	IS
E6								208	326	50	1.85	0.61	35	-60	0.38	CS
	E7	278	382	39	1.59	0.58	45										-50	0.55	CS

E8	270	355	52	1.85	0.28	21	-80	0.06	IS
										E9	271	359	48	1.75	0.28	28	-80	0.06	IS
E10	300	406	45	1.68	0.26	25	-60	0.07	IS
										E11	306	409	43	1.63	0.25	22	-60	0.07	IS
E12	363	459	35	1.45	0.21	26	-50	0.05	IS
										E13	231	346	45	1.79	0.61	49	-70	0.49	CS
E14	279	392	38	1.66	0.47	37	-60	0.51	CS
										E15	262	356	48	1.75	0.25	19	-80	0.07	IS
E16	265	350	48	1.75	0.23	17	-80	0.07	IS
										E17	310	405	42	1.63	0.22	18	-60	0.05	IS
E18	302	408	40	1.58	0.22	20	-60	0.05	IS
										E19	354	451	35	1.51	0.22	16	-50	0.06	IS
E20	212	339	47	1.74	0.49	37	-70	0.38	CS
										E21	279	393	43	1.64	0.42	39	-60	0.35	CS
E22	265	355	48	2.18	0.27	25	-80	0.06	IS
										E23	262	355	49	2.03	0.26	18	-80	0.06	IS
E24	252	356	47	2.03	0.31	15	-80	0.06	IS
										E25	224	357	47	1.82	0.32	0	-70	0.07	IS
E26	216	357	48	1.77	0.27	0	-80	0.07	IS
										E26	216	357	48	1.77	0.27	0	-80	0.07	IS
E27	222	350	47	1.72	0.25	0	-80	0.08	IS
										E28	210	361	48	2.12	0.38	0	-70	0.06	IS
E29	210	355	50	2.11	0.34	0	-70	0.08	IS
										E30	213	355	48	2.14	0.35	0	-70	0.08	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, IS=steel of the present invention, CS=compared steel

[embodiment 2-3] uses the sedimentary steel of high strength CuS-of AlN precipitation strength

After the temperature with the steel slab reheat to 1200 shown in the table 11 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 400 ℃/min, and 650 ℃ of rolling.Then, then hot rolled steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.Exceptionally, under the situation of sample F 8～F10, after being reheated 1250 ℃ temperature, then carry out finish rolling, with the speed cooling sample of 550 ℃/min, and then 650 ℃ of rolling.

Table 11

Sample number	Component (wt%)
												C	P	S	Al	N	Cu	Mo	V	R-4	R-3	R-2
	Content	≤0.003	0.03- 0.06	0.003- 0.025	0.01- 0.1	0.005- 0.02	0.01- 0.2	0.01- 0.2	0.01- 0.2	1- 10	1-5												1- 20
F1												0.0018	0.042	0.015	0.032	0.013	0.051			1.7	1.72
	F2	0.0023	0.04	0.012	0.032	0.0097	0.05			2.08	1.72
F3												0.0018	0.042	0.009	0.042	0.0072	0.086			4.78	3.03
	F4	0.0015	0.05	0.007	0.057	0.0080	0.123			8.79	3.71
F5												0.0025	0.043	0.01	0.042	0.0072	0.007			0.35	3.03
	F6	0.0022	0.042	0.009	0.038	0.0014	0.075			4.17	14.1
F7												0.0016	0.04	0.011	0.008	0.0028	0.01			0.45	1.49
	F8	0.0015	0.044	0.011	0.065	0.0077	0.037	0.022		1.68	4.39
F9												0.0022	0.044	0.011	0.043	0.011	0.056		0.019	2.55	2.03	2.16
	F10	0.0017	0.042	0.01	0.033	0.0092	0.035	0.022	0.017	1.75	1.87												2.5

Annotate: R-2=0.25*V/C, R-3=0.52*Al/N, R-4=0.5*Cu/S

Table 12

Sample number	Mechanical property							AS (μm)	Remarks
										YP (MPa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBTT (℃)
	F1	250	355	48	1.86	0.34	22										-70	0.04	IS
F2								259	362	48	1.82	0.34	25	-70	0.04	IS
	F3	262	352	46	1.85	0.38	23										-70	0.06	IS
F4								255	348	48	1.88	0.35	22	-70	0.07	IS
	F5	233	331	50	1.88	0.39	25										-70	0.21	CS
F6								221	320	48	1.83	0.42	26	-70	0.18	CS
	F7	218	322	49	1.82	0.34	49										-70	0.12	CS
F8								202	357	48	2.03	0.33	18	-70	0.08	IS
	F9	204	360	49	1.82	0.28	0										-80	0.06	IS
F10								202	357	49	2.23	0.43	0	-70	0.07	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, IS=steel of the present invention, CS=compared steel

The sedimentary steel of [embodiment 3-1] MnCu-

After the temperature with the steel slab reheat to 1200 shown in the table 13 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 600 ℃/min, and 650 ℃ of rolling.Then, then the rolling steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.Exceptionally, in table 13 under the situation of sample G10, after being reheated 1050 ℃ temperature, then carry out finish rolling, with the speed cooling sample of 50 ℃/min, and then 750 ℃ of rolling.

Table 13

Sample number	Component (wt%)
													C	Mn	P	S	Al	N	Cu	Mo	V	R-5	R-6	R-2
	≤0.003	0.03- 0.2	≤0.015	0.003- 0.025	0.01- 0.1	≤0.004	0.01- 0.2	0.01- 0.2	0.01- 0.2	≤0.3	2- 20	1- 20
													G1	0.0021	0.08	0.012	0.005	0.04	0.0023	0.082			0.16	16.2
G2	0.0018	0.11	0.009	0.009	0.04	0.0019	0.04			0.15	8.33
													G3	0.0022	0.09	0.012	0.011	0.05	0.0024	0.05			0.14	6.36
G4	0.0024	0.15	0.008	0.021	0.05	0.0018	0.04			0.19	4.52
													G5	0.0022	0.05	0.008	0.018	0.04	0.0024	0.035			0.09	2.36
G6	0.0024	0.4	0.011	0.012	0.05	0.0038	0.023			0.4	17.6
													G7	0.0028	0.05	0.012	0.018	0.04	0.0023	0.012			0.06	1.72
G8	0.0025	0.25	0.01	0.008	0.03	0.0015	0.18			0.4	26.9
													G9	0.0022	0.15	0.013	0.005	0.03	0.0026	0.12			0.27	27
G10	0.0025	0.1	0.010	0.010	0.03	0.0014	0.042			0.14	7.1
													G11	0.0023	0.11	0.01	0.011	0.024	0.0033	0.08	0.018		0.19	8.64
G12	0.0023	0.12	0.011	0.009	0.033	0.0023	0.082		0.021	0.20	11.2	2.28
													G13	0.0017	0.1	0.01	0.009	0.036	0.0032	0.042	0.019	0.023	0.14	7.89	3.38

Annotate: R-2=0.25*V/C, R-5=Mn+Cu, R-6=0.5* (Mn+Cu)/S

Table 14

Sample number	Mechanical property						AS (μm)	PN (quantity/mm 2)	Remarks
										YP (Mpa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)
	G1	198	292	51	2.32	0.38										17	0.09	4.5×10 6	IS
G2							208	309	52	2.35	0.35	16	0.08	9.4×10 6	IS

G3	221	314	55	2.51	0.26	21	0.06	2.2×10 8	IS
										G4	218	310	56	2.55	0.28	18	0.05	3.5×10 8	IS
G5	205	300	58	2.68	0.31	23	0.05	4.1×10 8	IS
										G6	175	282	58	2.83	0.93	35	0.38	8.5×10 4	CS
G7	163	270	60	2.78	1.12	36	0.48	4.3×10 4	CS
										G8	169	278	52	2.23	0.93	44	0.53	4.5×10 4	CS
G9	189	286	51	1.93	0.79	42	0.33	6.3×10 4	CS
										G10	181	291	55	2.45	0.88	35	0.38	7.1×10 4	CS
G11	209	302	50	2.83	0.45	25	0.09	3.5×10 6	IS
										G12	162	291	51	2.21	0.29	0	0.08	4.2×10 6	IS
G13	159	298	53	2.52	0.39	0	0.09	3.2×10 6	IS

Annotate: YP=yield strength, TS=tensile strength, El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, AI=ageing index, the sedimentary mean particle size of AS=, the sedimentary quantity of PN=, IS=steel of the present invention, CS=compared steel

The sedimentary steel of high strength MnCu-that [embodiment 3-2] strengthens with solid solution (solid solution)

After the temperature with the steel slab reheat to 1200 shown in the table 15 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 600 ℃/min, and 650 ℃ of rolling.Then, then the rolling steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.

Table 15

Sample number	Component (wt%)
															C	Mn	P	Si	Cr	S	Al	N	Cu	Mo	V	R-5	R-6	R-2
	≤0.003	0.03- 0.2	≤0.2	0.1- 0.8	0.2- 1.2	0.003- 0.025	0.01- 0.1	≤0.004	0.01- 0.2	0.01- 0.2	0.01- 0.2	≤0.3	2- 20	1- 20
															H1	0.0022	0.05	0.05			0.015	0.04	0.0018	0.03			0.08	2.67
H2	0.0015	0.08	0.048			0.015	0.03	0.0023	0.04			0.12	4
															H3	0.0027	0.07	0.105			0.02	0.05	0.0019	0.05			0.12	3
H4	0.0025	0.12	0.11			0.011	0.04	0.0038	0.08			0.2	9.09
															H5	0.0018	0.1	0.16			0.008	0.05	0.0012	0.14			0.24	15
H6	0.0018	0.05	0.05			0.015	0.02	0.0039	0.005			0.055	1.83
															H7	0.0022	0.1	0.109			0.011	0.05	0.0038	0.25			0.35	15.9
H8	0.0025	0.2	0.155			0.006	0.05	0.0038	0.08			0.28	23.3
															H9	0.0017	0.08	0.052			0.01	0.034	0.0018	0.043	0.022		0.12	6.15
H10	0.0027	0.1	0.05			0.014	0.034	0.0018	0.043		0.018	0.14	5.11	1.67
															H11	0.0017	0.11	0.052			0.012	0.024	0.0021	0.05	0.019	0.028	0.163	6.8	4.1
H12	0.0021	0.05	0.009	0.23		0.018	0.05	0.0023	0.03			0.08	2.22
															H13	0.0026	0.12	0.01	0.22		0.013	0.05	0.0026	0.03			0.15	5.77
H14	0.0016	0.1	0.012	0.40		0.018	0.04	0.0032	0.05			0.15	4.17
															H15	0.0021	0.12	0.012	0.40		0.015	0.04	0.0032	0.08			0.2	6.67
H16	0.0021	0.15	0.010	0.63		0.008	0.035	0.0012	0.141			0.291	18.2
															H17	0.0016	0.05	0.009	0.25		0.02	0.04	0.0028	0.005			0.055	1.38
H18	0.0021	0.18	0.011	0.43		0.006	0.04	0.0032	0.1			0.28	23.3
															H19	0.0022	0.3	0.009	0.60		0.015	0.05	0.0039	0.23			0.53	17.7
H20	0.0025	0.09	0.011	0.25		0.012	0.035	0.0013	0.032	0.02		0.122	5.08
															H21	0.002	0.1	0.01	0.23		0.009	0.03	0.0026	0.043		0.017	0.14	7.94	2.13
H22	0.0017	0.11	0.012	0.25		0.01	0.033	0.0036	0.045	0.018	0.019	0.16	7.75	2.79
															H23	0.0024	0.05	0.01		0.30	0.016	0.04	0.0022	0.04			0.09	2.81
H24	0.0018	0.12	0.009		0.32	0.012	0.05	0.0019	0.03			0.15	6.25
															H25	0.0024	0.12	0.01		0.6	0.015	0.04	0.0025	0.05			0.17	5.67
H26	0.0027	0.1	0.01		0.63	0.018	0.04	0.0025	0.04			0.14	3.89
															H27	0.0026	0.18	0.009		0.95	0.008	0.05	0.0022	0.08			0.26	16.3

H28	0.0017	0.05	0.01		0.32	0.02	0.04	0.0022	0.01			0.06	1.5
															H29	0.0023	0.15	0.01		0.62	0.005	0.05	0.0023	0.12			0.27	27
H30	0.0025	0.25	0.012		0.93	0.015	0.04	0.0024	0.29			0.54	18
															H31	0.0017	0.11	0.011		0.34	0.013	0.034	0.0029	0.043	0.018		0.15	5.88
H32	0.0016	0.09	0.01		0.32	0.036	0.0022	0.038	0.016		0.13	5.33	2.5
															H33	0.0018	0.1	0.012		0.34	0.01	0.026	0.0025	0.043	0.022	0.016	0.14	7.15	2.22

Annotate: R-2=0.25*V/C, R-5=Mn+Cu, R-6=0.5* (Mn+Cu)/S

Table 16

Sample number	Mechanical property							AS (μm)	PN (quantity/mm 2)	Remarks
											YP (Mpa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBTT (℃)
	H1	265	360	52	1.93	0.28	19											-70	0.05	4.5×10 8	IS
H2								255	358	53	2.09	0.28	14	-70	0.07	2.0×10 8	IS
	H3	302	405	45	1.79	0.22	17											-60	0.06	4.2×10 8	IS
H4								289	392	46	1.70	0.29	19	-50	0.06	7.5×10 6	IS
	H5	350	452	37	1.63	0.21	13											-40	0.09	2.3×10 6	IS
H6								228	327	47	1.75	0.65	38	-50	0.38	8.3×10 3	CS
	H7	282	385	39	1.59	0.55	45											-50	0.55	3.5×10 4	CS
H8								341	444	33	1.41	0.43	35	-40	0.61	2.3×10 4	CS
	H9	256	358	51	2.32	0.29	19											-70	0.06	6.5×10 8	IS
H10								204	362	50	1.89	0.21	0	-60	0.06	5.5×10 8	IS
	H11	213	366	49	2.31	2.8	0											-60	0.07	5.0×10 8	IS
H12								251	355	54	1.95	0.28	13	-80	0.07	4.9×10 8	IS
	H13	245	350	54	1.97	0.28	20											-80	0.14	8.5×10 6	IS
H14								296	405	45	1.73	0.25	13	-60	0.09	3.2×10 8	IS

H15	305	405	44	1.79	0.22	18	-60	0.07	4.1×10 8	IS
											H16	365	465	37	1.55	0.21	18	-50	0.17	2.2×10 6	IS
H17	231	336	45	1.79	0.61	42	-70	0.49	3.2×10 4	CS
											H18	279	382	40	1.63	0.57	40	-60	0.51	9.3×10 4	CS
H19	331	445	32	1.37	0.22	42	-40	0.43	6.7×10 4	CS
											H20	260	362	52	2.35	0.28	26	-80	0.07	3.8×10 8	IS
H21	208	360	50	1.89	0.23	0	-70	0.08	3.5×10 8	IS
											H22	203	352	51	2.21	0.27	0	-70	0.07	2.5×10 8	IS
H23	265	356	52	1.93	0.22	23	-80	0.06	5.9×10 8	IS
											H24	258	352	54	1.95	0.29	27	-70	0.07	4.4×10 8	IS
H25	298	395	45	1.62	0.22	22	-60	0.05	6.2×10 8	IS
											H26	302	405	46	1.58	0.20	23	-60	0.05	6.1×10 8	IS
H27	348	455	38	1.55	0.22	21	-50	0.06	2.2×10 6	IS
											H28	237	342	45	1.65	0.52	43	-70	0.35	4.2×10 4	CS
H29	275	390	41	1.54	0.42	42	-60	0.55	7.3×10 4	CS
											H30	335	440	32	1.38	0.25	38	-40	0.42	5.7×10 4	CS
H31	258	359	51	2.38	0.37	19	-80	0.07	6.9×10 8	IS
											H32	210	352	52	1.9	0.22	0	-70	0.07	5.6×10 8	IS
H33	204	349	52	2.21	0.36	0	-70	0.08	4.2×10 8	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, the AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, IS=steel of the present invention, the CS=compared steel, the CVS=conventional steel.

[embodiment 3-3] uses the sedimentary steel of high strength MnCu-of AlN precipitation strength

After the temperature with the steel slab reheat to 1200 shown in the table 17 ℃, then the finish rolling steel slab to be to provide hot rolled steel sheet, with the cooling hot-rolled steel sheet of the speed of 400 ℃/min, and 650 ℃ of rolling.Then, then the rolling steel sheet is carried out with 75% rate of compression cold rolling, then continuous annealing.Carry out finish rolling at 910 ℃, this temperature is higher than Ar ₃Transition temperature, and by ℃ carrying out continuous annealing 40 seconds with the speed of 10 ℃/s heating steel sheet to 750.

Table 17

Sample number	C	Mn	P	S	Al	N	Cu	Mo	V	R-5	R-6	R-3	R-2
														≤0.003	0.03- 0.2	0.03- 0.06	0.003- 0.025	0.01- 0.1	0.005- 0.02	0.01- 0.2	0.01- 0.2	0.01- 0.2	≤0.3	2-20	1-5	1- 20
	I1	0.0023	0.05	0.04	0.015	0.032	0.0097	0.03	-	-	0.08	2.67	1.72														-
I2														0.0018	0.1	0.042	0.012	0.042	0.0072	0.03	-	-	0.13	5.42	3.03	-
	I3	0.0021	0.1	0.05	0.01	0.057	0.0080	0.08	-	-	0.18	9	3.71														-
I4														0.0025	0.15	0.05	0.008	0.065	0.0075	0.1	-	-	0.25	15.63	4.51	-
	I5	0.0025	0.05	0.045	0.017	0.042	0.0072	0.01	-	-	0.06	1.76	3.03														-
I6														0.0022	0.15	0.04	0.009	0.038	0.0014	0.05	-	-	0.2	11.1	14.1	-
	I7	0.0016	0.15	0.05	0.005	0.05	0.0070	0.2	-	-	0.35	35	3.71														-
I8														0.0015	0.12	0.044	0.012	0.051	0.011	0.038	0.019	-	0.16	6.58	2.41	-
	I9	0.0018	0.1	0.041	0.009	0.045	0.0095	0.039	-	0.02	0.14	7.72	2.46														2.78
I10														0.0016	0.11	0.042	0.01	0.042	0.01	0.049	0.018	0.016	0.16	7.95	2.18	2.5

Annotate: R-2=0.25*V/C, R-3=0.52*Al/N, R-5=Mn+Cu, R-6=0.5* (Mn+Cu)/S

Table 18

Sample number	Mechanical property							AS (μm)	PN (quantity/mm 2)	Remarks
											YP (Mpa)	TS (MPa)	El (％)	R-value (r m)	Δ r-value (Δ r)	AI (MPa)	DBTT (℃)
	I1	246	352	54	1.96	0.29	22											-70	0.04	4.9×10 8	IS

I2	252	356	53	1.94	0.28	25	-70	0.05	3.5×10 8	IS
											I3	250	348	50	1.89	0.32	27	-60	0.07	3.2×10 6	IS
I4	255	350	48	1.86	0.35	22	-60	0.09	4.1×10 6	IS
											I5	243	340	43	1.68	0.39	36	-70	0.21	9.2×10 4	CS
I6	223	328	48	1.89	0.32	27	-70	0.09	9.3×10 6	CS
											I7	238	342	43	1.72	0.34	38	-70	0.32	9.3×10 4	CS
I8	244	350	54	2.32	0.39	18	-70	0.05	5.2×10 8	IS
											I9	195	349	53	1.93	0.21	0	-70	0.05	4.5×10 8	IS
I10	193	345	53	2.32	0.35	0	-70	0.06	4.8×10 8	IS

Annotate: the YP=yield strength, TS=tensile strength, the El=elongation, r-value: plasticity-anisotropic index, Δ r value: in-plane anisotropy index, the AI=ageing index, DBTT=is used to study the ductility-brittle transition temperature of secondary processing brittleness, the sedimentary mean particle size of AS=, the sedimentary quantity of PN=, IS=steel of the present invention, the CS=compared steel

Although disclosed the preferred embodiments of the present invention for illustrative purposes, those skilled in the art understands can carry out various modifications, increase and replacement, and does not break away from the disclosed scope and spirit of the present invention of accessory claim of the present invention.

Claims (81)

1. Cold Rolled Sheet Steel with resistance to deterioration and fabulous formability comprises: in 0.003% or still less the C of weight %; 0.003～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.03 at least a among～0.2% Mn and 0.005～0.2% the Cu; And the Fe of equal amount and other unavoidable impurities, wherein, when described steel sheet comprises a kind of among Mn and the Cu, the composition of Mn, Cu and S satisfies at least a relation: 0.58*Mn/S≤10 and 1≤0.5*Cu/S≤10, and when described steel sheet comprise Mn and Cu the two the time, the composition of Mn, Cu and S satisfies relation: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20, and wherein, MnS, CuS and (Mn, Cu) precipitation of S has 0.2 μ m or littler mean particle size.

2. Cold Rolled Sheet Steel with resistance to deterioration and fabulous formability comprises: in 0.003% or still less the C of weight %; 0.005～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.05～0.2% Mn; And the Fe of equal amount and other unavoidable impurities, wherein, Mn by weight and the composition of S satisfy relation: 0.58*Mn/S≤10, and wherein, the precipitation of MnS has 0.2 μ m or littler mean particle size.

3. steel sheet according to claim 2, wherein, described steel sheet comprises 0.015% or P still less.

4. steel sheet according to claim 2, wherein, described steel sheet comprises 0.004% or N still less.

5. steel sheet according to claim 2, wherein, described steel sheet comprises 0.03～0.2% P.

6. steel sheet according to claim 2 further comprises at least a among the Cr of 0.1～0.8% Si and 0.2～1.2%.

7. steel sheet according to claim 2, wherein, described steel sheet comprises 0.005～0.02% N and 0.03～0.06% P.

8. steel sheet according to claim 7, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

9. according to each described steel sheet in the claim 2 to 8, further comprise 0.01～0.2% Mo.

10. according to each described steel sheet in the claim 2 to 8, further comprise 0.01～0.2% V.

11. steel sheet according to claim 10, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

12. steel sheet according to claim 9 further comprises 0.01～0.2% V.

13. steel sheet according to claim 12, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

14. the Cold Rolled Sheet Steel with resistance to deterioration and fabulous formability comprises: in 0.0005～0.003% or still less the C of weight %; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.01～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Cu and S satisfies relation: 1≤0.5*Cu/S≤10, and wherein, the precipitation of CuS has 0.1 μ m or littler mean particle size.

15. steel sheet according to claim 14, wherein, described steel sheet comprises 0.015% or P still less.

16. steel sheet according to claim 14, wherein, described steel sheet comprises 0.004% or N still less.

17. steel sheet according to claim 14, wherein, the composition of described Cu and S satisfies relation: 1≤0.5*Cu/S≤3.

18. steel sheet according to claim 14, wherein, described steel sheet comprises 0.03～0.2% or P still less.

19. steel sheet according to claim 14 further comprises at least a 0.1～0.8% Si and 0.2～1.2% Cr.

20. steel sheet according to claim 14, wherein, described steel sheet comprises 0.005～0.02% N and 0.03～0.06% P.

21. steel sheet according to claim 20, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

22., further comprise 0.01～0.2% Mo according to each described steel sheet in the claim 14 to 21.

23., further comprise 0.01～0.2% V according to each described steel sheet in the claim 14 to 21.

24. steel sheet according to claim 23, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

25. steel sheet according to claim 22 further comprises 0.01～0.2% V.

26. steel sheet according to claim 25, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

27. the Cold Rolled Sheet Steel with resistance to deterioration and fabulous formability comprises: in 0.0005～0.003% or still less the C of weight %; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.03～0.2% Mn; 0.005～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn, Cu and S satisfies relation: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20, and wherein, MnS, CuS and (Mn, Cu)/precipitation of S has 0.2 μ m or littler mean particle size.

28. steel sheet according to claim 27, wherein, described steel sheet comprises 0.015% or P still less.

29. steel sheet according to claim 27, wherein, described steel sheet comprises 0.004% or N still less.

30. steel sheet according to claim 27, wherein, described sedimentary quantity is 2 * 10 ⁶Or it is more.

31. steel sheet according to claim 27, wherein, the composition of described Mn, Cu and S satisfies relation: 2≤0.5* (Mn+Cu)/S≤7.

32. steel sheet according to claim 31, wherein, described sedimentary quantity is 2 * 10 ⁸Or it is more.

33. steel sheet according to claim 27, wherein, described steel sheet comprises 0.03～0.2% or P still less.

34. steel sheet according to claim 27 further comprises at least a among the Cr of 0.1～0.8% Si and 0.2～1.2%.

35. steel sheet according to claim 27, wherein, described steel sheet comprises 0.005～0.02% N and 0.03～0.06% P.

36. steel sheet according to claim 35, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

37., further comprise 0.01～0.2% Mo according to each described steel sheet in the claim 27 to 36.

38., further comprise 0.01～0.2% V according to each described steel sheet in the claim 27 to 36.

39. according to the described steel sheet of claim 38, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

40., further comprise 0.01～0.2% V according to the described steel sheet of claim 39.

41. according to the described steel sheet of claim 37, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

42. a production has the method for the Cold Rolled Sheet Steel of resistance to deterioration and fabulous formability, comprises the following steps: after with steel slab reheat to 1100 ℃ or higher temperature the described steel slab of hot rolling and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature in order to hot rolled steel sheet to be provided, described steel slab comprises 0.003% or still less C in weight %; 0.005～0.03% S; 0.01～0.1% Al; 0.02% or N still less; 0.2% or P still less; 0.05～0.2% Mn; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn and S satisfies relation: 0.58*Mn/S≤10; Cool off described steel sheet with 200 ℃/min or faster speed; Described refrigerative steel sheet curls under 700 ℃ or lower temperature; Cold rolling described steel sheet; And the described Cold Rolled Sheet Steel of continuous annealing.

43. according to the described method of claim 42, wherein, described steel slab comprises 0.015% or P still less.

44. according to the described method of claim 42, wherein, described steel slab comprises 0.004% or N still less.

45. according to the described method of claim 42, wherein, described steel slab comprises 0.03～0.2% P.

46. according to the described method of claim 42, wherein, described steel slab further comprises at least a among the Cr of 0.1～0.8% Si and 0.2～1.2%.

47. according to the described method of claim 42, wherein, described steel slab comprises 0.005～0.02% N and 0.03～0.06% P.

48. according to the described method of claim 47, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

49. according to each described method in the claim 42 to 48, wherein, described steel slab further comprises 0.01～0.2% Mo.

50. according to each described method in the claim 42 to 48, wherein, described steel slab further comprises 0.01～0.2% V.

51. according to the described method of claim 50, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

52. according to the described method of claim 49, wherein, described steel slab further comprises 0.01～0.2% V.

53. according to the described method of claim 52, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

54. a production has the method for the Cold Rolled Sheet Steel of resistance to deterioration and fabulous formability, comprises the following steps: after with steel slab reheat to 1100 ℃ or higher temperature the described steel slab of hot rolling and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature in order to hot rolled steel sheet to be provided, described steel slab comprises 0.0005～0.003% C in weight %; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.01～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Cu and S satisfies relation: 1≤0.5*Cu/S≤10; Cool off described steel sheet with the speed of 300 ℃/min; Under 700 ℃ or lower temperature with described refrigerative steel sheet rolling; Cold rolling described rolling steel sheet; And the described Cold Rolled Sheet Steel of continuous annealing.

55. according to the described method of claim 54, wherein, described steel slab comprises 0.015% or P still less.

56. according to the described method of claim 54, wherein, described steel slab comprises 0.004% or N still less.

57. according to the described method of claim 54, wherein, the composition of described Cu and S satisfies relation: 1≤0.5*Cu/S≤3.

58. according to the described method of claim 54, wherein, described steel slab comprises 0.03～0.2% or P still less.

59. according to the described method of claim 54, wherein, described steel slab further comprises at least a among the Cr of 0.1～0.8% Si and 0.2～1.2%.

60. according to the described method of claim 54, wherein, described steel slab comprises 0.005～0.02% N and 0.03～0.06% P.

61. according to the described method of claim 60, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

62. according to each described method in the claim 54 to 61, wherein, described steel slab further comprises 0.01～0.2% Mo.

63. according to each described method in the claim 54 to 61, wherein, described steel slab further comprises 0.01～0.2% V.

64. according to the described method of claim 63, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

65., further comprise 0.01～0.2% V according to the described method of claim 62.

66. according to the described method of claim 65, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

67. a production has the method for the Cold Rolled Sheet Steel of resistance to deterioration and fabulous formability, comprises the following steps: after with steel slab reheat to 1100 ℃ or higher temperature hot rolled plate steel material and at Ar ₃Carry out finish rolling under texturing temperature or the higher temperature so that hot rolled steel sheet to be provided, described steel slab comprises 0.0005～0.003% C in weight %; 0.003～0.025% S; 0.01～0.08% Al; 0.02% or N still less; 0.2% or P still less; 0.03～0.2% Mn; 0.005～0.2% Cu; And the Fe of equal amount and other unavoidable impurities, wherein, the composition of Mn, Cu and S satisfies relation: Mn+Cu≤0.3 and 2≤0.5* (Mn+Cu)/S≤20; Cool off described steel sheet with the speed of 300 ℃/min; Under 700 ℃ or lower temperature with refrigerative steel sheet rolling; Cold rolling described rolling steel sheet; And the described Cold Rolled Sheet Steel of continuous annealing.

68. according to the described method of claim 67, wherein, described steel slab comprises 0.015% or P still less.

69. according to the described method of claim 67, wherein, described steel slab comprises 0.004% or N still less.

70. according to the described method of claim 67, wherein, described sedimentary quantity is 2 * 10 ⁶Or it is more.

71. according to the described method of claim 67, wherein, the composition of described Mn, Cu and S satisfies relation: 2≤0.5* (Mn+Cu)/S≤7.

72. according to the described method of claim 71, wherein, described sedimentary quantity is 2 * 10 ⁸Or it is more.

73. according to the described method of claim 67, wherein, described steel slab comprises 0.03～0.2% or P still less.

74. according to the described method of claim 67, wherein, described steel slab further comprises at least a among the Cr of 0.1～0.8% Si and 0.2～1.2%.

75. according to the described method of claim 67, wherein, described steel slab comprises 0.005～0.02% N and 0.03～0.06% P.

76. according to the described method of claim 75, wherein, the composition of described Al and N satisfies relation: 1≤0.52*Al/N≤5.

77. according to each described method in the claim 67 to 76, wherein, described steel slab further comprises 0.01～0.2% Mo.

78. according to each described method in the claim 67 to 76, wherein, described steel slab further comprises 0.01～0.2% V.

79. according to the described method of claim 78, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

80. according to the described method of claim 77, wherein, described steel slab further comprises 0.01～0.2% V.

81. 0 described method according to Claim 8, wherein, the composition of described V and C satisfies relation: 1≤0.25*V/C≤20.

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