Title of Invention	A PRODUCTION FACILITY OF HIGH STRENGTH STEEL SHEET OR HOT DIP ZINC COATED HIGH STRENGTH STEEL SHEET EXCELLENT IN ELONGATION AND HOLE EXPANDABILITY
Abstract	The present invention relates to a production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet being excellent in elongation and bore expanding characteristics, characterized in that a quenching device for cooling a steel sheet after recrystallization or after recrystallization and hot dip zinc plating to a temperature region of a martensite transformation point or lower, a tempering device for tempering said steel sheet and keeping the temperature thereof and a re-cooling device for cooling said steel sheet to 100&ring;C or lower are arranged in a continuous annealing device, a continuous hot dip zinc plating device or a device capable of being used for the two processes, or provided in connection with the continuous annealing or plating device.

Title of Invention

A PRODUCTION FACILITY OF HIGH STRENGTH STEEL SHEET OR HOT DIP ZINC COATED HIGH STRENGTH STEEL SHEET EXCELLENT IN ELONGATION AND HOLE EXPANDABILITY

Abstract

The present invention relates to a production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet being excellent in elongation and bore expanding characteristics, characterized in that a quenching device for cooling a steel sheet after recrystallization or after recrystallization and hot dip zinc plating to a temperature region of a martensite transformation point or lower, a tempering device for tempering said steel sheet and keeping the temperature thereof and a re-cooling device for cooling said steel sheet to 100&ring;C or lower are arranged in a continuous annealing device, a continuous hot dip zinc plating device or a device capable of being used for the two processes, or provided in connection with the continuous annealing or plating device.

Full Text	DESCRIPTION FACILITY FOR PRODUCTION OF HIGH STRENGTH STEEL SHEET OR HOT DIP ZINC COATED HIGH STRENGTH STEEL SHEET EXCELLENT IN ELONGATION AND HOLE EXPANDABILITY TECHNICAL FIELD The present invention relates to a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability. BACKGROUND ART In recent years, improvement of the fuel economy of motor vehicles and reduction of the weight of vehicle chasses have been demanded more strongly. To lighten weight, the need for high strength steel sheet has been rising. However, the higher the strength, the more difficult the formability becomes. In particular, the steel material falls in elongation. Further, depending on the member, there are quite a few parts where burring is performed to expand a machined hole to form a flange. Hole expandability also is starting to be demanded as an important characteristic. Therefore, to satisfy this demand, Japanese Patent Publication (A) No. 2001-192768, Japanese Patent Publication (A) No. 2001-200338, Japanese Patent Publication (A) No. 2001-3150, Japanese Patent Publication (A) No. 2001-207235, Japanese Patent Publication (A) No. 2001-207236, Japanese Patent Publication (A) No. 2002-38248, Japanese Patent Publication (A) No. 2002-309334, and Japanese Patent Publication (A) No. 2002-302734 propose to improve the hole expandability in TRIP steel or composite structure steel sheet by the technique of using tempered martensite and conducting annealing heat treatment twice. In this way, high strength steel sheet for which hole expandability is required is increasingly being given hot dip zinc coatings. On the other hand, there is also demand for high hole expandability high strength steel sheet without hot dip zinc coatings. In addition, relatively soft steel sheet used in the past for exterior panels of motor vehicles and steel sheet with extremely large deep drawability used for oil pans etc. have to be regularly produced. To produce such a large number of diverse types of steel sheet stably and efficiently, with a conventional single-objective type of continuous annealing facility continuously annealing steel sheet or a continuous annealing hot dip zinc coating facility able to continuously treat steel from annealing to hot dip zinc coating by a series of facilities, a plurality of such facilities have to be combined and passed through. This gives rise the problems of additional construction of facilities, lengthening of the production time, and increase in the production costs. DISCLOSURE OF THE INVENTION The present invention provide a facility able to efficiently produce, both cost-wise and time-wise, high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability used for auto parts etc. The inventors studied facilities for the production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability and as a result learned that by arranging in a continuous annealing facility or hot dip zinc coating facility or their joint facility or continuously with the same a quenching facility able to cool annealed steel sheet down to a temperature region of the martensite transformation point or less and a tempering facility for tempering the steel sheet and holding it in temperature enables the amount of tempered martensite to be freely controlled and is extremely important in securing and improving the elongation and hole expandability. That is, in the present invention, unlike the case where the quenching facility and the tempering facility are in separate production lines and a sheet is cooled down to ordinary temperature once between the quenching and tempering, by providing a series of continuous treatment facilities, it is possible to freely control the quenching/tempering temperature and possible to freely control the amount of tempered martensite, which plays a large role in the securing and improvement of the elongation and hole expansion rate, and the tensile strength. The gist of the present invention is as follows: (1) A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability characterized by arranging in a continuous annealing facility or a continuous hot dip zinc coating facility or their joint facility or continuously with the same a quenching facility able to cool steel sheet after recrystallization or after recrystallization and after hot dip zinc coating down to a temperature region of the martensite transformation point or less, a tempering facility for tempering the steel sheet and holding its temperature, and a recooling facility for cooling the steel sheet to 100°C or less. (2) A production facility for composite high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as set forth in (1) characterized in that a tempering temperature rise AT between the quenching facility and the tempering facility falls in a range of the following relationship (A) found from the post- tempering tensile strength TS and hole expansion rate X and in that a pre-tempering temperature T (°C) falls in a range of the following relationship (B) found from the post-tempering tensile strength TS and hole expansion rate λ. 0.028(1-28)TS-11.5λ-40 TS-7.5λ-90 ...(A) [{-2(λ-40) A2]/10A5]x(TS-580) A2-8U700 TS: post-tempering tensile strength (MPa) T: pre-tempering temperature T(°C) AT: tempering temperature rise (°C) (3) A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as set forth in (1) or (2) characterized in that the quenching facility has a cooling system of either of atomized water cooling, mist cooling, water spray cooling, or deep water cooling. (4) A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as set forth in (1), (2), or (3) characterized in that tempering facility has a heating system of induction heating. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory view of a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability of the present invention. FIG. 2 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 45% level of the final hole expansion value. FIG. 3 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 55% level of the final hole expansion value. FIG. 4 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 65% level of the final hole expansion value. FIG. 5 is an explanatory view of the relationship between the elongation and hole expansion rate in the present invention and the conventional method. BEST MODE FOR WORKING THE INVENTION Below, a facility for the production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability according to the present invention will be explained with reference to examples. Examples FIG. 1 is a schematic view showing the concept of a joint production facility for annealing of cold rolled steel sheet or hot rolled steel sheet and production of hot dip zinc coated steel sheet as an example of the present invention constituted by a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability. The facility for production of a high strength steel sheet or hot dip zinc coating in the present invention, as shown in FIG. 1, is comprised of an annealing and heating facility 1, annealing and cooling facility 2, holding facility 3, hot dip zinc coating facility 4, alloying facility 5, quenching facility 6, tempering facility 7, and recooling facility 8 successively arranged. Note that, in FIG. 1, the solid arrow shows the pass line at the time of production of a hot dip zinc coated steel sheet, the broken arrow shows the pass line at the time of annealing the cold rolled steel sheet or hot rolled steel sheet, that is, a pass line bypassing the hot dip zinc coating facility and returning to the original pass line before the alloying facility or quenching facility. (Example 1) Case of production of hot rolled or cold rolled high strength steel sheet When producing hot rolled or cold rolled steel sheet, in particular high strength steel sheet excellent in elongation and hole expandability, for example, hot rolled or cold rolled steel sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01,to 1.8%, and N: 0.0005 to 0.01% and having the balance of Fe and unavoidable impurities is heated by an annealing and heating facility 1 to Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then cooled by an annealing and cooling facility 2 by l°C/sec or more of a cooling rate to 450 to 60C°C in temperature. Next, in accordance with need, it is held by a holding facility 3 at 150 to 500°C in temperature for 10 seconds to 30 minutes, then, in the case of the "no-plating pass" of FIG. 1, route a is proceeded through so as to bypass the hot dip zinc coating facility 4, then as shown by the route b, the alloying facility 5, is passed through. Further, it is also possible to bypass even the alloying facility as shown by route c. Next, it is cooled by the quenching facility 6 by l°C/sec or more of a cooling rate down to a temperature region of the martensite transformation point or less, is held by the tempering facility 7 at 200°C to 500°C in temperature for I second to 5 minutes, and is cooled by the recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. Further, the above ranges of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to them. (Example 2) Case of production of hot dip zinc coated high strength steel sheet/quenching and tempering after hot dip zinc coating When producing hot rolled or cold rolled hot dip zinc coated high strength steel sheet, in particular hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability, for example, a plating sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01 to 1.8%, and N: 0.0005 to 0.01% and having the balance of Fe and unavoidable impurities is heated by the annealing and heating facility 1 to the Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then cooled by the annealing and cooling facility 2 by l°C/sec or more of a cooling rate down to 450 to 600°C in temperature. Next, in accordance with need, it is held by the holding facility 3 at 150 to 500°C in temperature for 10 seconds to 30 minutes, then is passed along the "plating pass" of FIG. 1 through a hot dip zinc coating facility 4 to give it a predetermined deposited weight of hot dip zinc coating. Further, in accordance with need, it is alloyed by the alloying facility 5. Next, it is cooled by the quenching facility 6 by l°C/sec or more of a cooling rate down to a temperature region of the martensite transformation point or less, then raised by the tempering facility 7 to 200°C to 500°C in temperature and held there for 1 second to 5 minutes, then cooled by a recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. Further, the ranges of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to these. (Example 3) Case of production of hot dip zinc coated high strength steel sheet/quenching and tempering before hot dip zinc coating When producing hot rolled or cold rolled hot dip zinc coated high strength steel sheet, in particular hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability, for example a plating sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01 to 1.8%, and N: 0.0005 to 0.01% and having the balance of Fe and unavoidable impurities is heated by the annealing and heating facility 1 to the Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then is cooled by the annealing and cooling facility 2 used as a quenching facility in the same way as the quenching facility 6 of Example 2 by l°C/sec or more of a cooling rate down to the temperature region of the martensite transformation point or less, is raised by the holding facility 3 used as a tempering facility in the same way as the tempering facility 7 of Example 2 to 200°C to 500°C in temperature and is held there for 1 second to 5 minutes. Further, it is passed along the "plating pass" of FIG. 1 through the hot dip zinc coating facility 4 to give it a predetermined deposited weight of hot dip zinc coating and, in accordance with need, is alloyed by the alloying facility 5. Next, it is cooled by the quenching facility 6 or recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. When it is cooled by the quenching facility 6 by a 5°C/sec or more cooling rate down to 100°C or less, the tempering facility 7 passes the sheet straight through without heating. When it is cooled by the recooling facility 8 by 5°C/sec or more of cooling rate down to 100°C or less, the quenching facility 6 and tempering facility 7 pass the sheet straight through without cooling or heating or else cooling or heating is not positively applied and the sheet is kept to the extent of holding its temperature. In this way etc., the facilities are suitably selectively used in accordance with the introduction of the hot dip zinc coated layer. Further, the range of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to this. As shown in Examples 1 to 3, the quenching/tempering facility is preferably arranged inside the continuous annealing facility or continuous hot dip zinc coating facility or their joint facility or continuously with the same. Further, as a preferable arrangement, in the case of a continuous annealing facility, the quenching/tempering facility is preferably arranged at the exit side of the annealing and cooling facility 2 or the exit side of the holding facility 3, while in the case of a continuous hot dip zinc coating facility, the quenching/tempering facility is preferably arranged continuously with the hot dip zinc coating facility 4 or alloying treatment facility 5. In the case of a joint facility of a continuous annealing facility and continuous hot dip zinc coating facility, it is possible to employ an arrangement of the quenching/tempering facility alone or in combination. In the case of a double use facility, arranging a quenching/tempering facility as shown in FIG. 1 is preferable in that it enables selection of the quenching/tempering and separate production before and after plating with or without plating, so the facility cost is low. As for the reason for arranging the quenching/tempering facility in the continuous annealing facility or hot dip zinc coating facility or their joint facility or continuously with the same being preferable, the inventors investigated the relationship between the tempering conditions and the hole expansion rate, whereupon they learned that the pre-tempering temperature, tempering temperature rise, post-tempering tensile strength, and hole expansion rate are in the relationships such as shown in FIGS. 2 to 4. Therefore, the inventors analyzed these relationships and discovered that when the pre-tempering temperature, tempering temperature rise, post-tempering tensile strength, and hole expansion rate satisfy th© relationship (A) and relationship (B), the necessary tempered martensite can be secured and superior formability and hole expandability can be secured. 0.028 (λ-28)TS-11.5λ-40 TS-7.5λ-90 ...(A) [{-2(λ-40)2]/105]x(TS-580)2-8λ+700 TS: post-tempering tensile strength (MPa) T: pre-tempering temperature T (°C) AT: tempering temperature rise (°C) If falling in the ranges of the above-mentioned relationship (A) and relationship (B) or if controlling them in the ranges in accordance with need, it is possible to obtain high strength steel sheet or hot dip zinc coated high strength steel sheet having a balance of the tensile strength and hole expansion rate in accordance with the user demands. Further, the above-mentioned hole expansion rate X is the rate when punching a 150 mm square test piece by a conical punch having a punching hole diameter of 10 mm, a clearance of 12%, and a peak angle of 60° and expanding the hole in a direction so that its burrs become the outside by a forming speed of 0.5 mm/sec. The amount of the tempered martensite of the high strength steel sheet obtained by the present invention is preferably, in terms of the area ratio, 0.5 to 60% in range. The tempered martensite is evaluated by the method of observation under an optical microscope, observation of the martensite by LePera etching, quantization by LePera etching, polishing of the sample (alumina finish), dipping in a corrosive solution (mixed solution of pure water, sodium pyrosulfite, ethyl alcohol, and picric acid) for 10 seconds, then again polishing, rinsing, then drying the sample by cold air. After drying, the structure of the sample was examined at 1000X for a 100 µm x 100 µmarea by a Luzex apparatus and measured for area to determine the area of the tempered martensite. Further, the tensile strength and elongation were evaluated by conducting a tensile test in a direction perpendicular to the rolling direction of a JIS No. 5 tensile test piece. Regarding the specifications of this quenching facility, since a certain extent of rapid cooling down to the martensite transformation point or less is required, atomized water cooling, mist cooling, water spray cooling, or deep water cooling is preferred, but even gas cooling may be used if giving an equal or better cooling rate as with atomized water cooling, mist cooling, water spray cooling, or deep water cooling. Further, regarding the specifications of this tempering facility, to obtain greater compactness of the facility or a reliable tempering effect in a short time, the heating system is preferably induction heating, but tempering by a gas burner, radiant tube oven, or electric heater oven may also be used if giving the same extent of greater compactness and reliable tempering effect in a short time as with induction heating. The cooling system of this recooling facility is not particularly limited, but if considering the unnecessary oxidation and discoloration of zinc plating, gas cooling is preferable. The continuous annealing facility or hot dip zinc coating facility or joint facility of the same for installation of the quenching/tempering facility may also include a pre-plating facility for improving the plating adhesion. Further, for adding surface lubrication, corrosion resistance, and chemical conversion treatment, various post-treatment facilities may also be provided at the exit sides of the continuous annealing facility or hot dip zinc coating facility or joint facility of the same. Next, the fact that use of the facility of the present invention is advantageous for the elongation and hole expandability of high strength steel sheet will be explained. Table 1 (Table Removed) For example, steel having the composition of ingredients of Table 1 was produced by a vacuum melting furnace, cooled to solidify, then reheated up to 1200 to 1240°C and finish rolled at 880 to 920°C (sheet thickness of 2.3 mm), cooled, then held at 600°C for 1 hour so as to reproduce the coiling heat treatment of hot rolling. The obtained hot rolled steel sheet was descaled by polishing, 7 cold rolled (1.2 mm), then annealed using a continuous annealing simulator at 750 to 880°C x 75 seconds, hot dip zinc coated at 490°C, then alloyed at 510°C. After that, it was treated under the conditions of Table 2 to confirm the effects of facilities according to the present invention. [1] to [3] are comparative examples constituted by conventional examples, wherein [1] shows the case of quenching as is with no tempering, [2] and [3] show the case of passage through a conventional continuous hot dip zinc coating facility and cooling (quenching) to ordinary temperature, then tempering by a separate line, and [4] to [7] show the case of treatment by the facility according to the present invention. Table 2 (Table Removed) As explained above, not only does the improvement in the material quality due to tempering by the facility of the present invention enable improvement of the hole expandability, but also the ability to control the quenching/ tempering temperature conditions to any conditions gives an effect of improvement of the material quality including improvement of the elongation. INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a facility able to efficiently produce, both cost-wise and time-wise, high strength steel sheet or ho! dip zinc coated high strength steel sheet excellent in elongation and hole expandability used for auto parts etc. and is extremely high in value industrially. WE CLAIM 1. A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability characterized by arranging in a continuous annealing facility or a continuous hot dip zinc coating facility or their joint facility or continuously with the same a quenching facility able to cool steel sheet after recrystallization or after recrystallization and after hot dip zinc coating down to a temperature region of the martensite transformation point or less, a tempering facility for tempering said steel sheet and holding its temperature, and a re-cooling facility for cooling said steel sheet to 100o Cor less, wherein a tempering temperature rise T between said quenching facility and said tempering facility falls in a range of the following relationship (A) found from the post-tempering tensile strength TS and hole expansion rate  and in that a pre-tempering temperature T (°C) falls in a range of the following relationship (B) found from the post-tempering tensile strength TS and hole expansion rate (Equation Removed) where,  : hole expansion rate (%) TS: post-tempering tensile strength (MPa) T: pre-tempering temperature T(°C) T: tempering temperature rise (°C ) 2. A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as claimed in claim 1, wherein the quenching facility has a cooling system of either of atomized water cooling, mist cooling, water spray cooling, or deep water cooling. 4. A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as claimed in claim 1 or 3, wherein the tempering facility has a heating system of induction heating.

Full Text

DESCRIPTION
FACILITY FOR PRODUCTION OF HIGH STRENGTH STEEL SHEET OR
HOT DIP ZINC COATED HIGH STRENGTH STEEL SHEET EXCELLENT
IN ELONGATION AND HOLE EXPANDABILITY
TECHNICAL FIELD
The present invention relates to a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability.
BACKGROUND ART
In recent years, improvement of the fuel economy of motor vehicles and reduction of the weight of vehicle chasses have been demanded more strongly. To lighten weight, the need for high strength steel sheet has been rising. However, the higher the strength, the more difficult the formability becomes. In particular, the steel material falls in elongation. Further, depending on the member, there are quite a few parts where burring is performed to expand a machined hole to form a flange. Hole expandability also is starting to be demanded as an important characteristic.
Therefore, to satisfy this demand, Japanese Patent Publication (A) No. 2001-192768, Japanese Patent Publication (A) No. 2001-200338, Japanese Patent Publication (A) No. 2001-3150, Japanese Patent Publication (A) No. 2001-207235, Japanese Patent Publication (A) No. 2001-207236, Japanese Patent Publication (A) No. 2002-38248, Japanese Patent Publication (A) No. 2002-309334, and Japanese Patent Publication (A) No. 2002-302734 propose to improve the hole expandability in TRIP steel or composite structure steel sheet by the technique of using tempered martensite and conducting annealing heat treatment twice.
In this way, high strength steel sheet for which hole expandability is required is increasingly being

given hot dip zinc coatings. On the other hand, there is also demand for high hole expandability high strength steel sheet without hot dip zinc coatings. In addition, relatively soft steel sheet used in the past for exterior panels of motor vehicles and steel sheet with extremely large deep drawability used for oil pans etc. have to be regularly produced.
To produce such a large number of diverse types of steel sheet stably and efficiently, with a conventional single-objective type of continuous annealing facility continuously annealing steel sheet or a continuous annealing hot dip zinc coating facility able to continuously treat steel from annealing to hot dip zinc coating by a series of facilities, a plurality of such facilities have to be combined and passed through. This gives rise the problems of additional construction of facilities, lengthening of the production time, and increase in the production costs.
DISCLOSURE OF THE INVENTION
The present invention provide a facility able to efficiently produce, both cost-wise and time-wise, high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability used for auto parts etc.
The inventors studied facilities for the production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability and as a result learned that by arranging in a continuous annealing facility or hot dip zinc coating facility or their joint facility or continuously with the same a quenching facility able to cool annealed steel sheet down to a temperature region of the martensite transformation point or less and a tempering facility for tempering the steel sheet and holding it in temperature enables the amount of tempered martensite to be freely controlled and is extremely important in securing and improving the elongation and hole

expandability. That is, in the present invention, unlike the case where the quenching facility and the tempering facility are in separate production lines and a sheet is cooled down to ordinary temperature once between the quenching and tempering, by providing a series of continuous treatment facilities, it is possible to freely control the quenching/tempering temperature and possible to freely control the amount of tempered martensite, which plays a large role in the securing and improvement of the elongation and hole expansion rate, and the tensile strength.
The gist of the present invention is as follows:
(1) A production facility for high strength steel
sheet or hot dip zinc coated high strength steel sheet
excellent in elongation and hole expandability
characterized by arranging in a continuous annealing
facility or a continuous hot dip zinc coating facility or
their joint facility or continuously with the same a
quenching facility able to cool steel sheet after
recrystallization or after recrystallization and after
hot dip zinc coating down to a temperature region of the
martensite transformation point or less, a tempering
facility for tempering the steel sheet and holding its
temperature, and a recooling facility for cooling the
steel sheet to 100°C or less.
(2) A production facility for composite high
strength steel sheet or hot dip zinc coated high strength
steel sheet excellent in elongation and hole
expandability as set forth in (1) characterized in that a
tempering temperature rise AT between the quenching
facility and the tempering facility falls in a range of
the following relationship (A) found from the post-
tempering tensile strength TS and hole expansion rate X
and in that a pre-tempering temperature T (°C) falls in a
range of the following relationship (B) found from the
post-tempering tensile strength TS and hole expansion

rate λ.
0.028(1-28)TS-11.5λ-40 TS-7.5λ-90 ...(A)
[{-2(λ-40) A2]/10A5]x(TS-580) A2-8U700 TS: post-tempering tensile strength (MPa) T: pre-tempering temperature T(°C) AT: tempering temperature rise (°C)
(3) A production facility for high strength steel
sheet or hot dip zinc coated high strength steel sheet
excellent in elongation and hole expandability as set
forth in (1) or (2) characterized in that the quenching
facility has a cooling system of either of atomized water
cooling, mist cooling, water spray cooling, or deep water
cooling.
(4) A production facility for high strength steel
sheet or hot dip zinc coated high strength steel sheet
excellent in elongation and hole expandability as set
forth in (1), (2), or (3) characterized in that tempering
facility has a heating system of induction heating.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an explanatory view of a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability of the present invention.
FIG. 2 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 45% level of the final hole expansion value.
FIG. 3 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 55% level of the final hole expansion value.
FIG. 4 is an explanatory view of the relationship between the pre-tempering temperature and TS at the 65% level of the final hole expansion value.
FIG. 5 is an explanatory view of the relationship

between the elongation and hole expansion rate in the present invention and the conventional method.
BEST MODE FOR WORKING THE INVENTION
Below, a facility for the production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability according to the present invention will be explained with reference to examples.
Examples
FIG. 1 is a schematic view showing the concept of a joint production facility for annealing of cold rolled steel sheet or hot rolled steel sheet and production of hot dip zinc coated steel sheet as an example of the present invention constituted by a facility for production of high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability.
The facility for production of a high strength steel sheet or hot dip zinc coating in the present invention, as shown in FIG. 1, is comprised of an annealing and heating facility 1, annealing and cooling facility 2, holding facility 3, hot dip zinc coating facility 4, alloying facility 5, quenching facility 6, tempering facility 7, and recooling facility 8 successively arranged. Note that, in FIG. 1, the solid arrow shows the pass line at the time of production of a hot dip zinc coated steel sheet, the broken arrow shows the pass line at the time of annealing the cold rolled steel sheet or hot rolled steel sheet, that is, a pass line bypassing the hot dip zinc coating facility and returning to the original pass line before the alloying facility or quenching facility.
(Example 1) Case of production of hot rolled or cold rolled high strength steel sheet
When producing hot rolled or cold rolled steel sheet, in particular high strength steel sheet excellent in elongation and hole expandability, for example, hot

rolled or cold rolled steel sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01,to 1.8%, and N: 0.0005 to 0.01% and having the balance of Fe and unavoidable impurities is heated by an annealing and heating facility 1 to Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then cooled by an annealing and cooling facility 2 by l°C/sec or more of a cooling rate to 450 to 60C°C in temperature. Next, in accordance with need, it is held by a holding facility 3 at 150 to 500°C in temperature for 10 seconds to 30 minutes, then, in the case of the "no-plating pass" of FIG. 1, route a is proceeded through so as to bypass the hot dip zinc coating facility 4, then as shown by the route b, the alloying facility 5, is passed through. Further, it is also possible to bypass even the alloying facility as shown by route c. Next, it is cooled by the quenching facility 6 by l°C/sec or more of a cooling rate down to a temperature region of the martensite transformation point or less, is held by the tempering facility 7 at 200°C to 500°C in temperature for I second to 5 minutes, and is cooled by the recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. Further, the above ranges of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to them.
(Example 2) Case of production of hot dip zinc coated high strength steel sheet/quenching and tempering after hot dip zinc coating
When producing hot rolled or cold rolled hot dip zinc coated high strength steel sheet, in particular hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability, for example, a plating sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01 to 1.8%, and N: 0.0005 to 0.01% and having the

balance of Fe and unavoidable impurities is heated by the annealing and heating facility 1 to the Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then cooled by the annealing and cooling facility 2 by l°C/sec or more of a cooling rate down to 450 to 600°C in temperature. Next, in accordance with need, it is held by the holding facility 3 at 150 to 500°C in temperature for 10 seconds to 30 minutes, then is passed along the "plating pass" of FIG. 1 through a hot dip zinc coating facility 4 to give it a predetermined deposited weight of hot dip zinc coating. Further, in accordance with need, it is alloyed by the alloying facility 5. Next, it is cooled by the quenching facility 6 by l°C/sec or more of a cooling rate down to a temperature region of the martensite transformation point or less, then raised by the tempering facility 7 to 200°C to 500°C in temperature and held there for 1 second to 5 minutes, then cooled by a recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. Further, the ranges of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to these.
(Example 3) Case of production of hot dip zinc coated high strength steel sheet/quenching and tempering before hot dip zinc coating
When producing hot rolled or cold rolled hot dip zinc coated high strength steel sheet, in particular hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability, for example a plating sheet containing by wt% C: 0.01 to 0.3%, Si: 0.005 to 2%, Mn: 0.1 to 3.3%, P: 0.001 to 0.06%, S: 0.001 to 0.01%, Al: 0.01 to 1.8%, and N: 0.0005 to 0.01% and having the balance of Fe and unavoidable impurities is heated by the annealing and heating facility 1 to the Aci to Ac3+100°C in temperature over 30 seconds to 30 minutes, then is cooled by the annealing and cooling facility 2 used as a quenching facility in the same way as the quenching

facility 6 of Example 2 by l°C/sec or more of a cooling rate down to the temperature region of the martensite transformation point or less, is raised by the holding facility 3 used as a tempering facility in the same way as the tempering facility 7 of Example 2 to 200°C to 500°C in temperature and is held there for 1 second to 5 minutes. Further, it is passed along the "plating pass" of FIG. 1 through the hot dip zinc coating facility 4 to give it a predetermined deposited weight of hot dip zinc coating and, in accordance with need, is alloyed by the alloying facility 5. Next, it is cooled by the quenching facility 6 or recooling facility 8 by 5°C/sec or more of a cooling rate down to 100°C or less. When it is cooled by the quenching facility 6 by a 5°C/sec or more cooling rate down to 100°C or less, the tempering facility 7 passes the sheet straight through without heating. When it is cooled by the recooling facility 8 by 5°C/sec or more of cooling rate down to 100°C or less, the quenching facility 6 and tempering facility 7 pass the sheet straight through without cooling or heating or else cooling or heating is not positively applied and the sheet is kept to the extent of holding its temperature. In this way etc., the facilities are suitably selectively used in accordance with the introduction of the hot dip zinc coated layer. Further, the range of ingredients, temperature conditions, etc. are preferable ranges. The invention is not particularly limited to this.
As shown in Examples 1 to 3, the quenching/tempering facility is preferably arranged inside the continuous annealing facility or continuous hot dip zinc coating facility or their joint facility or continuously with the same. Further, as a preferable arrangement, in the case of a continuous annealing facility, the quenching/tempering facility is preferably arranged at the exit side of the annealing and cooling facility 2 or the exit side of the holding facility 3, while in the

case of a continuous hot dip zinc coating facility, the quenching/tempering facility is preferably arranged continuously with the hot dip zinc coating facility 4 or alloying treatment facility 5. In the case of a joint facility of a continuous annealing facility and continuous hot dip zinc coating facility, it is possible to employ an arrangement of the quenching/tempering facility alone or in combination. In the case of a double use facility, arranging a quenching/tempering facility as shown in FIG. 1 is preferable in that it enables selection of the quenching/tempering and separate production before and after plating with or without plating, so the facility cost is low.
As for the reason for arranging the
quenching/tempering facility in the continuous annealing facility or hot dip zinc coating facility or their joint facility or continuously with the same being preferable, the inventors investigated the relationship between the tempering conditions and the hole expansion rate, whereupon they learned that the pre-tempering temperature, tempering temperature rise, post-tempering tensile strength, and hole expansion rate are in the relationships such as shown in FIGS. 2 to 4. Therefore, the inventors analyzed these
relationships and discovered that when the pre-tempering
temperature, tempering temperature rise, post-tempering
tensile strength, and hole expansion rate satisfy th©
relationship (A) and relationship (B), the necessary
tempered martensite can be secured and superior
formability and hole expandability can be secured.
0.028 (λ-28)TS-11.5λ-40 TS-7.5λ-90 ...(A)
[{-2(λ-40)2]/105]x(TS-580)2-8λ+700 TS: post-tempering tensile strength (MPa)

T: pre-tempering temperature T (°C) AT: tempering temperature rise (°C)
If falling in the ranges of the above-mentioned relationship (A) and relationship (B) or if controlling them in the ranges in accordance with need, it is possible to obtain high strength steel sheet or hot dip zinc coated high strength steel sheet having a balance of the tensile strength and hole expansion rate in accordance with the user demands.
Further, the above-mentioned hole expansion rate X is the rate when punching a 150 mm square test piece by a conical punch having a punching hole diameter of 10 mm, a clearance of 12%, and a peak angle of 60° and expanding the hole in a direction so that its burrs become the outside by a forming speed of 0.5 mm/sec.
The amount of the tempered martensite of the high strength steel sheet obtained by the present invention is preferably, in terms of the area ratio, 0.5 to 60% in range. The tempered martensite is evaluated by the method of observation under an optical microscope, observation of the martensite by LePera etching, quantization by LePera etching, polishing of the sample (alumina finish), dipping in a corrosive solution (mixed solution of pure water, sodium pyrosulfite, ethyl alcohol, and picric acid) for 10 seconds, then again polishing, rinsing, then drying the sample by cold air. After drying, the structure of the sample was examined at 1000X for a 100 µm x 100 µmarea by a Luzex apparatus and measured for area to determine the area of the tempered martensite. Further, the tensile strength and elongation were evaluated by conducting a tensile test in a direction perpendicular to the rolling direction of a JIS No. 5 tensile test piece.
Regarding the specifications of this quenching facility, since a certain extent of rapid cooling down to the martensite transformation point or less is required,

atomized water cooling, mist cooling, water spray cooling, or deep water cooling is preferred, but even gas cooling may be used if giving an equal or better cooling rate as with atomized water cooling, mist cooling, water spray cooling, or deep water cooling.
Further, regarding the specifications of this tempering facility, to obtain greater compactness of the facility or a reliable tempering effect in a short time, the heating system is preferably induction heating, but tempering by a gas burner, radiant tube oven, or electric heater oven may also be used if giving the same extent of greater compactness and reliable tempering effect in a short time as with induction heating.
The cooling system of this recooling facility is not particularly limited, but if considering the unnecessary oxidation and discoloration of zinc plating, gas cooling is preferable.
The continuous annealing facility or hot dip zinc coating facility or joint facility of the same for installation of the quenching/tempering facility may also include a pre-plating facility for improving the plating adhesion. Further, for adding surface lubrication, corrosion resistance, and chemical conversion treatment, various post-treatment facilities may also be provided at the exit sides of the continuous annealing facility or hot dip zinc coating facility or joint facility of the same.
Next, the fact that use of the facility of the present invention is advantageous for the elongation and hole expandability of high strength steel sheet will be explained.

Table 1

(Table Removed)
For example, steel having the composition of ingredients of Table 1 was produced by a vacuum melting furnace, cooled to solidify, then reheated up to 1200 to 1240°C and finish rolled at 880 to 920°C (sheet thickness of 2.3 mm), cooled, then held at 600°C for 1 hour so as to reproduce the coiling heat treatment of hot rolling. The obtained hot rolled steel sheet was descaled by polishing, 7 cold rolled (1.2 mm), then annealed using a continuous annealing simulator at 750 to 880°C x 75 seconds, hot dip zinc coated at 490°C, then alloyed at 510°C. After that, it was treated under the conditions of Table 2 to confirm the effects of facilities according to the present invention.
[1] to [3] are comparative examples constituted by conventional examples, wherein [1] shows the case of quenching as is with no tempering, [2] and [3] show the case of passage through a conventional continuous hot dip zinc coating facility and cooling (quenching) to ordinary temperature, then tempering by a separate line, and [4] to [7] show the case of treatment by the facility according to the present invention.
Table 2
(Table Removed)
As explained above, not only does the improvement in the material quality due to tempering by the facility of the present invention enable improvement of the hole expandability, but also the ability to control the quenching/ tempering temperature conditions to any conditions gives an effect of improvement of the material quality including improvement of the elongation.
INDUSTRIAL APPLICABILITY
According to the present invention, it is possible to provide a facility able to efficiently produce, both cost-wise and time-wise, high strength steel sheet or ho! dip zinc coated high strength steel sheet excellent in elongation and hole expandability used for auto parts etc. and is extremely high in value industrially.

WE CLAIM
1. A production facility for high strength steel sheet or hot dip zinc coated high
strength steel sheet excellent in elongation and hole expandability characterized by arranging in a continuous annealing facility or a continuous hot dip zinc coating facility or their joint facility or continuously with the same a quenching facility able to cool steel sheet after recrystallization or after recrystallization and after hot dip zinc coating down to a temperature region of the martensite transformation point or less, a tempering facility for tempering said steel sheet and holding its temperature, and a re-cooling facility for cooling said steel sheet to 100o Cor less,
wherein a tempering temperature rise T between said quenching facility and said tempering facility falls in a range of the following relationship (A) found from the post-tempering tensile strength TS and hole expansion rate  and in that a pre-tempering temperature T (°C) falls in a range of the following relationship (B) found from the post-tempering tensile strength TS and hole expansion rate
(Equation Removed)
where,  : hole expansion rate (%)
TS: post-tempering tensile strength (MPa)
T: pre-tempering temperature T(°C)
T: tempering temperature rise (°C )
2. A production facility for high strength steel sheet or hot dip zinc coated high strength steel sheet excellent in elongation and hole expandability as claimed in claim 1, wherein the quenching facility has a cooling system of either of atomized water cooling, mist cooling, water spray cooling, or deep water cooling.
4. A production facility for high strength steel sheet or hot dip zinc coated high
strength steel sheet excellent in elongation and hole expandability as claimed in claim 1 or 3, wherein the tempering facility has a heating system of induction heating.

Documents:

3313-DELNP-2007-Abstract-(19-11-2010).pdf

3313-delnp-2007-abstract.pdf

3313-DELNP-2007-Claims-(19-11-2010).pdf

3313-delnp-2007-claims.pdf

3313-DELNP-2007-Correspondence-Others-(19-11-2010).pdf

3313-DELNP-2007-Correspondence-Others-(27-08-2010).pdf

3313-DELNP-2007-Correspondence-Others-(29-12-2010).pdf

3313-delnp-2007-correspondence-others.pdf

3313-delnp-2007-description (complete).pdf

3313-delnp-2007-drawings.pdf

3313-delnp-2007-form-1.pdf

3313-delnp-2007-form-18.pdf

3313-delnp-2007-form-2.pdf

3313-delnp-2007-form-26.pdf

3313-DELNP-2007-Form-3-(29-12-2010).pdf

3313-delnp-2007-form-3.pdf

3313-delnp-2007-form-5.pdf

3313-delnp-2007-pct-210.pdf

3313-delnp-2007-pct-304.pdf

3313-delnp-2007-pct-308.pdf

3313-delnp-2007-pct-311.pdf

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Patent Number

249006

Indian Patent Application Number

3313/DELNP/2007

PG Journal Number

38/2011

Publication Date

23-Sep-2011

Grant Date

21-Sep-2011

Date of Filing

03-May-2007

Name of Patentee

NIPPON STEEL CORPORATION

Applicant Address

6-3 OTEMACHI 2-CHOME, CHIYODA-KU TOKYO 100-8071, JAPAN

Inventors:

#	Inventor's Name	Inventor's Address
1	SATOSHI KATO	C/O NIPPON STEEL CORPORATION NAGOYA WORKS, 5-3, TOKAIMACHI, TOKAIO-SHI, AICHI 476-8686, JAPAN
2	HIROKAZU TANIGUCHI	C/O NIPPON STEEL CORPORATION TECHNICAL DEVELOPMENT BUREAU, 20-1, SHINTOMI, FUTTSU-SHI, CHIBA 293-8511, JAPAN
3	TOSHIKI NONAKA	C/O NIPPON STEEL CORPORATION NAGOYA WORKS, 5-3, TOKAIMACHI, TOKAIO-SHI, AICHI 476-8686, JAPAN
4	HIROKI MURAYAMA	C/O NIPPON STEEL CORPORATION NAGOYA WORKS, 5-3, TOKAIMACHI, TOKAIO-SHI, AICHI 476-8686, JAPAN
5	KOJI YANABA	C/O NIPPON STEEL CORPORATION NAGOYA WORKS, 5-3, TOKAIMACHI, TOKAIO-SHI, AICHI 476-8686, JAPAN

PCT International Classification Number

C21D 9/46

PCT International Application Number

PCT/JP2005/020977

PCT International Filing date

2005-11-09

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2004-335598	2004-11-19	Japan