Ultra-low carbon steel composition, the process of...

Alloys or metallic compositions – Ferrous – Titanium containing

Reexamination Certificate

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C420S127000, C148S533000, C148S603000, C148S320000

Reexamination Certificate

active

06623691

ABSTRACT:

FIELD OF THE INVENTION
The present invention is related to an ultra-low carbon steel composition. The present invention is also related to a process of production of an ultra low carbon bake hardenable steel having said composition. The present invention is also related to the end product of said process.
BACKGROUND OF THE INVENTION
In the automobile industry there is a need for hot dip galvanized or galvannealed ultra-low carbon bake hardenable steel (also called ULC BH steel) having excellent dent resistance and very good paint appearance.
Several documents are describing such ULC BH products having either titanium (obtained by the so called Ti-route) or titanium-niobium (obtained by Ti/Nb-route).
More particularly, document EP-A-0064552 describes a method of producing a thin steel sheet having a high baking hardenability and adapted for drawing. The document describes a method comprising the steps of forming a molten steel having a composition containing 0.002-0.015% by weight of C; 0.04-1.5% of Mn; not more than 1.2% of Si; not more than 0.10% of P; 0.001-0.01% of N; 0.01-0.10% of Al, and Nb in an amount within the range (in %) from 2C to 8C+0.02 into a slab, hot rolling the slab, cold rolling the hot rolled sheet, subjecting the cold rolled sheet to a continuous annealing at a uniform temperature between 900° C. and the Ac
3
point, and cooling the annealed sheet to a temperature of not higher than 600° C. at an average cooling rate of at least 1° C. per second, preferably at least 10° C. per second.
However drawbacks of this process are the high soaking temperature necessary to dissolve carbides and the fact that a high cooling rate after soaking is necessary to prevent reprecipitation of these carbides. Other disadvantages are the fact that beside the carbon content which must be controlled in a narrow range, also the Nb/C ratio in the steelmaking plant has to be controlled, and finally that, due to the use of Al for binding the N, high coiling temperatures are preferably used in order to prevent deterioration of mechanical and aging properties at the coil ends in case of continuously annealed steel. Higher coiling temperatures are disadvantageous for the pickling of the hot rolled steel before cold rolling.
Document JP-10280092 describes a hot dip galvanized steel sheet having minimal age deterioration in press formability and good baking finish hardenability. This steel has a composition comprising C, Si, Mn, P, S, Al, N, Ti, Nb, Fe and if necessary B, and is providing a metallic structure in which a specific volume percentage of iron carbide exists in the ferrite grain boundary. This metallic structure is formed by subjecting a slab of steel with the above composition to finish rolling at a temperature not lower than the A
r3
point, performing cold rolling at 65-95%, and then applying continuous hot dip galvanizing and temper rolling to the resultant steel sheet under respectively controlled conditions.
However, iron carbide precipitation in such kind of ULC steels was never detected in the as produced condition due to the very low amounts of carbon and the short times during which these low amounts can precipitate in a continuous annealing process. On the other hand, segregated atomic carbon in grain boundaries has long been physically known.
No BH
0
values are mentioned. Also, according to the document, finishing rolling must be performed not lower than the A
r3
point which becomes more difficult in case of alloying with P and Si. No minimum Nb addition is specified in the abstract. Ti is added as a function of N and S-contents.
Document JP-5059443 describes a process of fabrication of a steel sheet having good formability which comprises the steps of adding Ti and Nb in relation with the C, N, S contents, while controlling carbonitride in an ultra-low carbon steel having a specific composition where Ti and Nb are combinedly added. This steel is hot-rolled at a finishing temperature (T2) higher than or equal to (A
r3
−100)° C., coiled at a temperature (T3) between 500 and 750° C., and cold-rolled with a reduction of area higher or equal to 60%. Subsequently, this steel sheet is subjected to recrystallization annealing at 700-850° C. by means of a continuous hot-dip galvanizing line having an in-line annealing furnace, and galvanizing is done in the course of cooling. By this method, a hot dip galvanized cold rolled steel sheet having required baking hardenability (BH characteristic) and formability can be obtained.
In particular, JP-5059443 requires that the Nb-content comply with the following condition: Nb≧93/12[C−0.0015], wherein the Nb and C-contents are expressed in weight %. However, Nb addition as a function of carbon is an extra difficulty to realize in an industrial steelmaking plant.
Document EP-A-0816524 describes a cold-rolled steel sheet or a zinc or zinc alloy layer coated steel sheet containing 0.0010 to 0.01% of C and having a steel composition containing one or two kinds of 0.005 to 0.08% of Nb and 0.01 to 0.07% of Ti in the ranges given by specific relations. However, Nb and Ti are added specifically to have a minimum amount of fine NbC and/or TiC not less than 5 ppm, in order to get higher n-values. Moreover, said document gives explicitly a range for BH
2
between 10 and 35 MPa, without mentioning BH
0
values
Document JP05263185 describes a steel grade where the BH is in fact obtained by annealing in the two-phase (&agr;+&ggr;) region followed by cooling which leads to a final acicular ferritic structure with a high dislocation density. A high Mn-content is needed in order to decrease the transformation temperatures. In order to have a good texture in the presence of a high Mn-content, free carbon during the recrystallization has to be avoided and is therefore being precipitated by Ti and Nb, before annealing is started. In the two-phase region some of these carbides are then dissolved providing free carbon. However, even with the large Mn-additions, the Ac1 temperatures are still high and annealing in the high temperature two-phase region is technologically a high cost-increasing factor.
Document JP04080323 describes a Ti-ULC BH steel which may contain 10-40 ppm Nb, without impairing the aimed properties. The claimed analysis also specifies a maximum N-content of 20 pppm, which is a high restriction for the steelmaking plant. However, prior research and industrial trial results have shown that with such Ti-ULC BH grades with a low <40 ppm Nb addition, low yield strength occurs at the zinc bath temperature, which has a negative effect on the surface appearance of such steel sheets. The bad surface appearance of steel sheet obtained through the Ti-route is a consequence of small deformations, which are caused in the zinc bath and its immediate surroundings, by the high tensile stress in the zinc bath section and by the guiding rolls, which position the sheet between the air knives. In fact, the sum of the tensile stress generated by both the tensile forces applied to control the band behavior as well as the stress induced in the outer surface layers by bending of the sheet on the rolls in the zinc bath and by the imbricator rolls, may not exceed the yield strength of the material at the elevated temperatures of the zinc bath and its surroundings. The appearance is indeed increasingly bad at higher line tensile stresses and higher out of line imbricator roll positioning.
After stamping and before painting, this effect can be visualized on a Marciniak sample by way of transversal lines, even on sheets which have undergone the skinpass treatment and have been labeled as suitable for exposed parts. After the final painting of the surface, it exhibits an orangepeel-like appearance with high waviness. Due to this phenomenon, it can be expected that steels with a low yield strength (less than 220-240 MPa at room temperature) are most likely to suffer from this, which has indeed been verified in laboratory tests.
SUMMARY OF THE INVENTION
The present invention is related to an ultra-low carbon steel composition i

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