JP6468404B1 - Steel plate and manufacturing method thereof, crown and DRD can - Google Patents

Steel plate and manufacturing method thereof, crown and DRD can Download PDF

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JP6468404B1
JP6468404B1 JP2018541433A JP2018541433A JP6468404B1 JP 6468404 B1 JP6468404 B1 JP 6468404B1 JP 2018541433 A JP2018541433 A JP 2018541433A JP 2018541433 A JP2018541433 A JP 2018541433A JP 6468404 B1 JP6468404 B1 JP 6468404B1
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房亮 假屋
房亮 假屋
卓嗣 植野
卓嗣 植野
嘉秀 山本
嘉秀 山本
克己 小島
克己 小島
文吾 舘野
文吾 舘野
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    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D9/00Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
    • C21D9/46Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor for sheet metals
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C38/00Ferrous alloys, e.g. steel alloys
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C38/00Ferrous alloys, e.g. steel alloys
    • C22C38/60Ferrous alloys, e.g. steel alloys containing lead, selenium, tellurium, or antimony, or more than 0.04% by weight of sulfur

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Abstract

質量%で、C:0.0060%超0.0100%以下、Si:0.05%以下Mn:0.05%以上0.60%以下、P:0.050%以下、S:0.050%以下、Al:0.020%以上0.050%以下およびN:0.0070%以上0.0140%以下を含有し、残部はFeおよび不可避的不純物の成分組成と、板厚の1/4の深さから板厚中心部までの領域にフェライト粒径の標準偏差が7.0μm以下のフェライト相を有する組織とするとともに、降伏強度を560MPa以上とすることによって、薄肉化しても十分な強度と優れた成形性を備える鋼板を提供する。In mass%, C: more than 0.0060% and 0.0100% or less, Si: 0.05% or less, Mn: 0.05% or more and 0.60% or less, P: 0.050% or less, S: 0.050 % Or less, Al: 0.020% or more and 0.050% or less and N: 0.0070% or more and 0.0140% or less, with the balance being the component composition of Fe and inevitable impurities and 1/4 of the plate thickness. With a structure having a ferrite phase with a standard deviation of ferrite grain size of 7.0 μm or less in the region from the depth to the center of the plate thickness, the yield strength is set to 560 MPa or more, so that sufficient strength can be obtained even if the thickness is reduced And a steel sheet having excellent formability.

Description

本発明は、鋼板、特に成形性に優れる高強度薄鋼板およびその製造方法に関するものである。このような鋼板の典型例としては、絞り加工と再絞り加工とを組み合わせて成形されるDRD(Drawing and Redrawing)缶の他、ガラス瓶などの栓として用いられる王冠の素材として供する、薄鋼板がある。さらに、本発明は、前記鋼板を成形して得られる王冠およびDRD缶に関するものである。   The present invention relates to a steel plate, particularly a high-strength thin steel plate excellent in formability and a method for producing the same. Typical examples of such steel sheets include DRD (Drawing and Redrawing) cans formed by combining drawing and redrawing, and thin steel sheets used as crown materials used as stoppers for glass bottles and the like. . Furthermore, the present invention relates to a crown and a DRD can obtained by forming the steel plate.

さて、清涼飲料水や酒類などの飲料用の容器には、従来ガラス瓶が多く用いられている。特に、細口のガラス瓶には、王冠と呼ばれる金属製の栓が広く用いられている。一般的に、王冠は、薄鋼板を素材としてプレス成形によって製造され、瓶の口を塞ぐ円盤状の部分と、その周囲に設けられた襞状の部分からなり、襞状の部分を瓶の口にかしめることによって瓶を密封する。   Conventionally, many glass bottles are used for containers for beverages such as soft drinks and alcoholic beverages. In particular, metal caps called crowns are widely used for narrow-mouthed glass bottles. Generally, a crown is manufactured by press-molding a thin steel plate, and consists of a disk-shaped part that closes the mouth of the bottle and a bowl-shaped part around it. Seal the jar by caulking.

王冠が用いられる瓶には、ビールや炭酸飲料など、高い内圧を生じる内容物が充填されることが多い。このため、温度の変化などで内圧が高まった場合にも、王冠が変形して瓶の密封が破られることがないように、王冠には、高い耐圧強度が必要である。また、素材の強度が十分であっても、王冠に用いられる鋼板の材質均一性が低い場合は、王冠の形状が不揃いになって製品規格から外れるものが含まれることになる。このような不良形状の王冠を瓶の口にかしめても十分な密封性が得られない場合が生じるため、王冠の素材となる鋼板は材質均一性に優れていることも必要である。   Bottles in which crowns are used are often filled with contents that produce high internal pressure, such as beer and carbonated drinks. For this reason, even when the internal pressure increases due to a change in temperature or the like, the crown needs to have high pressure strength so that the crown is not deformed and the sealing of the bottle is not broken. Moreover, even if the strength of the material is sufficient, if the material uniformity of the steel plate used for the crown is low, the shape of the crown is not uniform, and those that are out of product specifications are included. Even if such a poorly shaped crown is caulked to the mouth of the bottle, sufficient sealing performance may not be obtained. Therefore, the steel plate used as the crown material must also be excellent in material uniformity.

王冠の素材に供する薄鋼板には、主にSR(Single Reduced)鋼板が用いられている。これは、冷間圧延により鋼板を薄くした後に、焼鈍を施し、調質圧延を行うものである。従来の王冠用鋼板の板厚は、一般的に0.22mm以上であり、食品や飲料の缶などに用いる軟鋼を素材としたSR材を適用することで十分な耐圧強度と成形性を確保することが可能であった。   SR (Single Reduced) steel sheet is mainly used as the thin steel sheet used for the crown material. In this method, after thinning a steel sheet by cold rolling, annealing is performed and temper rolling is performed. The sheet thickness of conventional steel plates for crowns is generally 0.22 mm or more, and sufficient compressive strength and formability are ensured by applying SR material made of mild steel used for food and beverage cans and the like. It was possible.

近年、缶用鋼板と同様に、王冠用鋼板についてもコストダウンを目的とした薄肉化の要求が高まっている。王冠用鋼板の板厚が、0.22mm未満とりわけ0.20mm以下になると、従来のSR材で製造した王冠では耐圧強度が不足することになる。王冠用鋼板として耐圧強度を確保するためには、薄肉化に伴う強度の低下を補う必要があり、焼鈍後に再度冷間圧延を施して加工硬化させる、DR(Double Reduced)鋼板が適用されている。   In recent years, as with steel plates for cans, there is an increasing demand for thinning the crown steel plate for the purpose of reducing costs. When the plate thickness of the steel plate for the crown is less than 0.22 mm, particularly 0.20 mm or less, the pressure strength is insufficient in the crown manufactured with the conventional SR material. In order to ensure the compressive strength as a steel plate for crowns, it is necessary to compensate for the decrease in strength due to thinning, and a DR (Double Reduced) steel plate that is cold-rolled and annealed after annealing is applied. .

ところで、王冠は、成形初期に中央部がある程度絞られ、その後、外縁部が襞形状に成形される。ここで、王冠の素材が材質均一性の低い鋼板であると、該鋼板から製造される、王冠は外径および高さが不揃いになって製品規格から外れることがある。王冠の外径および高さが不揃いになって製品規格から外れるものがあると、大量に王冠を製造した際の歩留りが低下するといった問題がある。さらに、外径および高さが規格を外れた王冠は、瓶に打栓された後の輸送中に内容物の漏洩が生じ易く、蓋としての役割を果たさないといった問題もある。また、王冠の外径および高さが製品規格内であっても、鋼板強度が低い場合には、耐圧強度不足により王冠が外れる可能性がある。   By the way, the center of the crown is squeezed to some extent at the initial stage of molding, and then the outer edge is molded into a bowl shape. Here, if the material of the crown is a steel plate with low material uniformity, the crown manufactured from the steel plate may have irregular outer diameters and heights, which may be out of product specifications. If the outer diameter and height of the crown become uneven, and there are things that deviate from the product specification, there is a problem that the yield when a large number of crowns are manufactured decreases. Furthermore, a crown whose outer diameter and height are out of specification is liable to cause leakage of contents during transportation after being plugged into a bottle, and has a problem that it does not serve as a lid. Even if the outer diameter and height of the crown are within the product specification, if the steel plate strength is low, the crown may be removed due to insufficient pressure strength.

また、DRD缶の素材として、材質均一性の低い鋼板を適用すると、DRD缶の成形時に缶のフランジ部に発生する皺に代表される、形状不良をまねく可能性がある。このDRD缶についても、形状不良により製品規格から外れるものがあると、大量にDRD缶を製造した際の歩留りが低下するという、上記した王冠の場合と同様の問題となる。   In addition, when a steel plate with low material uniformity is applied as a material of the DRD can, there is a possibility of causing a shape defect typified by wrinkles generated at the flange portion of the can when the DRD can is formed. Even if this DRD can deviates from the product standard due to a defective shape, it causes the same problem as in the case of the above-mentioned crown that the yield when a large number of DRD cans are manufactured decreases.

以上の点を踏まえた、王冠用の高強度薄鋼板について、例えば特許文献1には、質量%で、C:0.0010%以上0.0060%以下、Si:0.005%以上0.050%以下、Mn:0.10%以上0.50%以下、P:0.040%以下、S:0.040%以下、Al:0.1000%以下、N:0.0100%以下を含有し、圧延方向に対して25〜65°の方向のr値の最小値と全方向のr値の平均値、および降伏強度を適切に制御することにより、薄厚でも十分な王冠耐圧を満たす王冠用鋼板およびその製造方法が開示されている。   Regarding the high-strength thin steel sheet for crowns based on the above points, for example, in Patent Document 1, in mass%, C: 0.0010% or more and 0.0060% or less, Si: 0.005% or more and 0.050 %: Mn: 0.10% or more and 0.50% or less, P: 0.040% or less, S: 0.040% or less, Al: 0.1000% or less, N: 0.0100% or less The steel plate for a crown satisfying a sufficient crown pressure resistance even with a thin thickness by appropriately controlling the minimum value of the r value in the direction of 25 to 65 ° with respect to the rolling direction, the average value of the r value in all directions, and the yield strength. And a method of manufacturing the same.

特許第6057023号公報Japanese Patent No. 6057023

特許文献1に記載の鋼板は、0.0060%以下のCを含有した鋼を用い、二次冷間圧延におけるスタンド間張力と焼鈍温度を所定の関係とすることにより、王冠加工に適したr値(方向・大きさ)を得ている。この方法は、金属組織形成に影響を及ぼす熱間圧延工程を制御していないために、得られる鋼板は材質のばらつきが大きくなり、実用に供するのは困難である。   The steel sheet described in Patent Document 1 uses steel containing 0.0060% or less of C, and has a predetermined relationship between the tension between the stands and the annealing temperature in secondary cold rolling. Value (direction / size) is obtained. Since this method does not control the hot rolling process that affects the formation of the metal structure, the obtained steel sheet has a large variation in material, and is difficult to put into practical use.

本発明は、上記課題に鑑みてなされたものであって、その目的は、薄肉化しても十分な強度と優れた成形性を備える鋼板およびその製造方法を提供することにある。さらに、本発明の目的は、所定の寸法および形状に整えられる、形状安定性に優れる王冠およびDRD缶を提供することにある。   This invention is made | formed in view of the said subject, The objective is to provide the steel plate provided with sufficient intensity | strength and the outstanding formability even if it thins, and its manufacturing method. Furthermore, an object of the present invention is to provide a crown and a DRD can which are adjusted to a predetermined size and shape and have excellent shape stability.

発明者らは、上記した課題を解決するための方途について鋭意究明したところ、所定の成分組成の下に組織を規制することによって、高強度かつ優れた成形性を付与できることを見出した。本発明はこの知見に由来するものであり、その要旨構成は次のとおりである。   The inventors diligently studied how to solve the above-mentioned problems, and found that high strength and excellent moldability can be imparted by regulating the structure under a predetermined component composition. The present invention is derived from this finding, and the gist of the present invention is as follows.

(1)質量%で、
C:0.0060%超0.0100%以下、
Si:0.05%以下、
Mn:0.05%以上0.60%以下、
P:0.050%以下、
S:0.050%以下、
Al:0.020%以上0.050%以下および
N:0.0070%以上0.0140%以下
を含有し、残部はFeおよび不可避的不純物の成分組成を有し、
板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下であり、
降伏強度が560MPa以上である鋼板。
(1) In mass%,
C: more than 0.0060% and 0.0100% or less,
Si: 0.05% or less,
Mn: 0.05% or more and 0.60% or less,
P: 0.050% or less,
S: 0.050% or less,
Al: 0.020% or more and 0.050% or less and N: 0.0070% or more and 0.0140% or less, with the balance having a component composition of Fe and inevitable impurities,
Having a ferrite phase in the region from the depth of 1/4 of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7.0 μm or less,
A steel sheet having a yield strength of 560 MPa or more.

(2)板厚が0.20mm以下である前記(1)に記載の鋼板。 (2) The steel plate according to (1), wherein the plate thickness is 0.20 mm or less.

(3)前記(1)または(2)に記載の鋼板からなる王冠。 (3) A crown made of the steel sheet according to (1) or (2).

(4)前記(1)または(2)に記載の鋼板からなるDRD缶。 (4) A DRD can comprising the steel plate according to (1) or (2).

(5)前記(1)または(2)に記載の鋼板の製造方法であり、
鋼素材を1200℃以上で加熱し、仕上げ圧延温度:870℃以上および最終スタンドの圧下率:10%以上の条件にて圧延を施して550〜750℃の温度範囲内で巻取る熱間圧延工程と、
前記熱間圧延後の熱延板に酸洗を行う酸洗工程と、
前記酸洗後の熱延板に、圧下率:88%以上の冷間圧延を行う一次冷間圧延工程と、
前記一次冷間圧延後の冷延板を、660〜760℃の温度域に60秒以下で保持したのち、10℃/s以上の平均冷却速度で450℃以下の温度域まで冷却し、次いで5℃/s以上の平均冷却速度で140℃以下の温度域まで冷却する焼鈍工程と、
前記焼鈍板に、10%以上40%以下の圧下率で冷間圧延を行う二次冷間圧延工程と、を有する鋼板の製造方法。
(5) The method for producing a steel sheet according to (1) or (2),
A hot rolling process in which a steel material is heated at 1200 ° C. or higher, finished rolling temperature: 870 ° C. or higher and the rolling reduction of the final stand: 10% or higher, and wound in a temperature range of 550 to 750 ° C. When,
Pickling step of pickling the hot-rolled sheet after hot rolling;
A primary cold rolling step of performing cold rolling with a reduction ratio of 88% or more on the hot-rolled sheet after pickling,
The cold-rolled sheet after the primary cold rolling is held in a temperature range of 660 to 760 ° C. for 60 seconds or less, and then cooled to a temperature range of 450 ° C. or less at an average cooling rate of 10 ° C./s or more. An annealing step of cooling to a temperature range of 140 ° C. or lower at an average cooling rate of at least C / s;
A secondary cold rolling step of performing cold rolling on the annealed plate at a rolling reduction of 10% to 40%.

本発明によれば、薄肉化しても十分な強度を有しかつ材質均一性に優れる鋼板を、その有利な製造方法と共に提供することができる。さらに、本発明の鋼板を例えば王冠用あるいはDRD缶用に供した場合に、形状に歪みのない王冠あるいはDRD缶を成形することができる。   ADVANTAGE OF THE INVENTION According to this invention, the steel plate which has sufficient intensity | strength and is excellent in material uniformity even if it thins can be provided with the advantageous manufacturing method. Furthermore, when the steel plate of the present invention is used for, for example, a crown or a DRD can, a crown or a DRD can having no shape distortion can be formed.

本発明に係る鋼板は、質量%で、C:0.0060%超0.0100%以下、Si:0.05%以下、Mn:0.05%以上0.60%以下、P:0.050%以下、S:0.050%以下、Al:0.020%以上0.050%以下、N:0.0070%以上0.0140%以下を含有し、残部はFeおよび不可避的不純物からなる成分組成を有し、板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下である。
まず、鋼板の成分組成における各成分量の限定理由から順に説明する。なお、成分に関する「%」表示は、特に断らない限り「質量%」を示す。
The steel sheet according to the present invention is in mass%, C: more than 0.0060% and 0.0100% or less, Si: 0.05% or less, Mn: 0.05% or more and 0.60% or less, P: 0.050. %: S: 0.050% or less, Al: 0.020% or more and 0.050% or less, N: 0.0070% or more and 0.0140% or less, with the balance being Fe and inevitable impurities It has a composition and has a ferrite phase in a region from a depth of ¼ of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7.0 μm or less.
First, it demonstrates in order from the reason for limitation of each component amount in the component composition of a steel plate. In addition, unless otherwise indicated, the "%" display regarding a component shows "mass%".

C:0.0060%超0.0100%以下
Cの含有量を0.0060%以下とすると、後述の二次冷間圧延後の鋼板のフェライトが粗大となって成形性が悪化し、例えば王冠用に供した場合に、成形した王冠外径および王冠高さが不均一となる。同様に、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生し形状不良の缶となる。一方、C含有量が0.0100%超となると、二次冷間圧延後の鋼板のフェライトが微細となりすぎて鋼板強度が過剰に上昇して成形性が劣化し、例えば王冠用に供した場合に、成形した王冠の外径および高さが不均一となる。同様に、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生し形状不良の缶となる。よって、Cの含有量は0.0060%超0.0100%以下とする。好ましくは、Cの含有量は0.0065%以上0.0090%以下とする。
C: more than 0.0060% and 0.0100% or less When the C content is 0.0060% or less, the ferrite of the steel sheet after the secondary cold rolling described later becomes coarse and the formability deteriorates. When it is used for the purpose, the outer diameter and the height of the formed crown are not uniform. Similarly, when it is used for a DRD can, for example, wrinkles are generated in the flange portion when the DRD can is formed, resulting in a poorly shaped can. On the other hand, when the C content exceeds 0.0100%, the ferrite of the steel sheet after the secondary cold rolling becomes too fine, the steel sheet strength is excessively increased, and the formability deteriorates, for example, when used for a crown Further, the outer diameter and height of the molded crown are not uniform. Similarly, when it is used for a DRD can, for example, wrinkles are generated in the flange portion when the DRD can is formed, resulting in a poorly shaped can. Therefore, the C content is more than 0.0060% and 0.0100% or less. Preferably, the C content is 0.0065% or more and 0.0090% or less.

Si:0.05%以下
Siを多く含むとCと同様の理由により、例えば王冠用に供した場合に、王冠の外径および高さの均一性が損なわれ、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。よって、Siの含有量は0.05%以下とする。また、過剰にSiを低下させることは製鋼コストの増大を招くため、Siの含有量は0.004%以上とすることが好ましい。より好ましくは、0.01%以上0.03%以下である。
Si: 0.05% or less When containing a large amount of Si, for the same reason as C, for example, when used for the crown, the outer diameter and the uniformity of the height of the crown are impaired. For example, when used for a DRD can In addition, it causes a shape defect in which wrinkles are generated in the flange portion during DRD can molding. Therefore, the Si content is 0.05% or less. Moreover, since excessively reducing Si causes an increase in steelmaking cost, the Si content is preferably 0.004% or more. More preferably, it is 0.01% or more and 0.03% or less.

Mn:0.05%以上0.60%以下
Mnの含有量が0.05%を下回ると、Sの含有量を低下させても熱間脆化を回避することが困難になり、連続鋳造時に表面割れなどの問題が生じる。よって、Mnの含有量は0.05%以上とする。一方、Mnを多く含むと、Cと同様の理由により、例えば王冠用に供した場合に、王冠の外径および高さの均一性が損なわれ、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。よって、Mnの含有量は0.60%以下とする。好ましくは、Mnの含有量は0.10%以上0.50%以下である。
Mn: 0.05% or more and 0.60% or less When the content of Mn is less than 0.05%, it becomes difficult to avoid hot embrittlement even if the content of S is reduced. Problems such as surface cracks occur. Therefore, the Mn content is 0.05% or more. On the other hand, when Mn is contained in a large amount, the uniformity of the outer diameter and height of the crown is impaired when used for a crown, for example, for the same reason as C. For example, when used for a DRD can, a DRD can This leads to shape defects that cause wrinkles in the flange during molding. Therefore, the Mn content is set to 0.60% or less. Preferably, the Mn content is 0.10% or more and 0.50% or less.

P:0.050%以下
Pの含有量が0.050%を超えると、鋼板の硬質化や耐食性の低下が引き起こされる。また、焼鈍後のフェライト粒径の標準偏差が7.0μm超となって成形性が悪化し、例えば王冠用に供した場合に、王冠の外径および高さの均一性が損なわれ、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。よって、Pの含有量の上限値は0.050%とする。また、Pを0.001%未満とするには脱Pコストが過大となるため、Pの含有量は0.001%以上とすることが好ましい。
P: 0.050% or less When the P content exceeds 0.050%, the steel sheet is hardened and the corrosion resistance is lowered. Further, the standard deviation of the ferrite grain size after annealing exceeds 7.0 μm and the formability deteriorates. For example, when used for a crown, the uniformity of the outer diameter and height of the crown is impaired. When used for cans, it leads to shape defects that cause wrinkles in the flanges during DRD can molding. Therefore, the upper limit of the P content is 0.050%. Further, in order to make P less than 0.001%, the removal P cost becomes excessive, so the content of P is preferably made 0.001% or more.

S:0.050%以下
Sは、鋼板中でMnと結合してMnSを形成し、多量に析出することで鋼板の熱間延性を低下させる。Sの含有量が0.050%を超えるとこの影響が顕著となる。よって、Sの含有量の上限値は0.050%とする。また、Sを0.005%未満とするには脱Sコストが過大となるため、Sの含有量は0.004%以上とすることが好ましい。
S: 0.050% or less S combines with Mn in a steel plate to form MnS, and precipitates in a large amount to lower the hot ductility of the steel plate. This effect becomes significant when the S content exceeds 0.050%. Therefore, the upper limit of the S content is 0.050%. Further, in order to make S less than 0.005%, the removal S cost becomes excessive, so the S content is preferably made 0.004% or more.

Al:0.020%以上0.050%以下
Alは、脱酸剤として含有させる元素であり、また鋼中のNとAlNを形成し、鋼中の固溶Nを減少させる。Al含有量が0.020%未満であると脱酸剤としての効果が不十分になり、凝固欠陥の発生を招くとともに製鋼コストが増大する。また、0.020%未満のAl量とすると、焼鈍でのフェライトの再結晶時に適切な量のAlNを確保できないため、焼鈍後のフェライト粒径の標準偏差が大きくなり、二次冷間圧延後の鋼板のフェライトが粗大となって成形性が悪化する。すると、例えば王冠用に供した場合に、王冠の外径および高さの均一性が損なわれ、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。一方、Alの含有量が0.050%超となると、AlNの形成が増加して、後述する固溶Nとして鋼板強度に寄与するN量が低減し、鋼板強度が低下するため、Al含有量は0.050%以下とする。好ましくは、Al含有量は0.030%以下0.045%以下である。
Al: 0.020% or more and 0.050% or less Al is an element to be contained as a deoxidizing agent, and forms N and AlN in the steel to reduce the solid solution N in the steel. If the Al content is less than 0.020%, the effect as a deoxidizer becomes insufficient, causing solidification defects and increasing the steelmaking cost. Also, if the amount of Al is less than 0.020%, an appropriate amount of AlN cannot be ensured during recrystallization of ferrite during annealing, so the standard deviation of the ferrite grain size after annealing increases, and after secondary cold rolling The ferrite of the steel sheet becomes coarse and the formability deteriorates. Then, for example, when used for a crown, the uniformity of the outer diameter and height of the crown is impaired, and when used for a DRD can, for example, it leads to a shape defect that causes wrinkles in the flange portion during DRD can molding. On the other hand, when the Al content exceeds 0.050%, the formation of AlN increases, the amount of N contributing to the steel sheet strength as solute N described later decreases, and the steel sheet strength decreases. Is 0.050% or less. Preferably, the Al content is 0.030% or less and 0.045% or less.

N:0.0070%以上0.0140%以下
Nの含有量を0.0070%未満とすると、二次冷間圧延後の鋼板のフェライトが粗大となって成形性が悪化し、例えば王冠用に供した場合に、成形した王冠の外径および高さが不均一となるとともに、後述する固溶Nとして鋼板強度に寄与するN量が低減し、鋼板強度が低下する。同様に、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生し形状不良の缶となる。一方、N含有量が0.0140%超となると二次冷間圧延後の鋼板のフェライトが微細となりすぎて鋼板強度が過剰に上昇して成形性が劣化し、例えば王冠用に供した場合に、王冠の外径および高さの均一性が損なわれ、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。好ましくは、Nの含有量は0.0085以上0.0125%以下とする。より好ましくは、0.0100%超とする。
以上の成分以外の残部は、Feおよび不可避的不純物とする。
N: 0.0070% or more and 0.0140% or less When the N content is less than 0.0070%, the ferrite of the steel sheet after the secondary cold rolling becomes coarse and the formability deteriorates. For example, for the crown When provided, the outer diameter and height of the molded crown are not uniform, and the amount of N that contributes to the steel sheet strength as solute N described later is reduced, and the steel sheet strength is reduced. Similarly, when it is used for a DRD can, for example, wrinkles are generated in the flange portion when the DRD can is formed, resulting in a poorly shaped can. On the other hand, when the N content exceeds 0.0140%, the ferrite of the steel sheet after the secondary cold rolling becomes too fine, the steel sheet strength is excessively increased and the formability deteriorates, for example, when used for a crown. The uniformity of the outer diameter and height of the crown is impaired. For example, when it is used for a DRD can, it causes a shape defect in which a wrinkle is generated in the flange portion when the DRD can is formed. Preferably, the N content is 0.0085 or more and 0.0125% or less. More preferably, it is over 0.0100%.
The balance other than the above components is Fe and inevitable impurities.

次に、本発明に係る鋼板の金属組織は、少なくとも板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下であることが肝要である。
まず、本発明の鋼板の金属組織は、フェライト相を主体とし残部はセメンタイトであり、フェライト相は85体積%以上であることが好ましい。より好ましくは、90%以上である。すなわち、フェライト相が85体積%未満では、加工時に硬質なセメンタイトを起点に破断が発生し易くなり、成形性が劣化する。
Next, the metal structure of the steel sheet according to the present invention has a ferrite phase at least in a region from a depth of ¼ of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7 It is important that the thickness is 0.0 μm or less.
First, the metal structure of the steel sheet of the present invention is preferably composed mainly of a ferrite phase, the balance being cementite, and the ferrite phase being 85% by volume or more. More preferably, it is 90% or more. That is, when the ferrite phase is less than 85% by volume, breakage tends to occur starting from hard cementite during processing, and formability deteriorates.

以上の金属組織において、少なくとも板厚の1/4の深さから板厚中心部までの領域のフェライト相におけるフェライト粒径の標準偏差が7.0μm以下とする。
すなわち、フェライト粒径の標準偏差が7.0μm超となると成形性が悪化し、例えば王冠用に供した場合に、成形後の王冠の外径および高さが不均一となり、耐圧強度が低下するとともに、王冠を製造する際の歩留りが低下する。同様に、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生し形状不良の缶となる。好ましくは、フェライト粒径の標準偏差は6.5μm以下である。
In the metal structure described above, the standard deviation of the ferrite grain size in the ferrite phase in the region from at least a quarter of the plate thickness to the center of the plate thickness is set to 7.0 μm or less.
That is, when the standard deviation of the ferrite grain size exceeds 7.0 μm, the formability deteriorates. For example, when used for a crown, the outer diameter and height of the crown after molding become non-uniform, and the pressure strength decreases. At the same time, the yield when manufacturing the crown decreases. Similarly, when it is used for a DRD can, for example, wrinkles are generated in the flange portion when the DRD can is formed, resulting in a poorly shaped can. Preferably, the standard deviation of the ferrite grain size is not more than 6.5 μm.

ここで、フェライトの金属組織は、鋼板圧延方向に平行な板厚方向の断面を研磨後、腐食液(3体積%ナイタール)で腐食し、400倍の倍率で10視野にわたり光学顕微鏡で板厚1/4深さ位置(上記断面における、表面から板厚方向に板厚の1/4の位置)から板厚1/2位置までの領域を観察し、光学顕微鏡で撮影した組織写真を用いてフェライトを目視判定により特定し、画像解析によりフェライトの粒径を求める。各視野でフェライト粒径の粒度分布を求めて、標準偏差を算出し、10視野の標準偏差を平均した値をフェライト粒径の標準偏差とする。画像解析は、オリンパス株式会社の画像解析ソフトウェア 「Stream Essentials」を使用した。   Here, the ferrite microstructure is corroded with a corrosive liquid (3% by volume nital) after polishing a cross section in the plate thickness direction parallel to the rolling direction of the steel plate, and the plate thickness is 1 with an optical microscope over 10 fields of view at 400 × magnification. / 4 Observe the region from the depth position (in the cross section, 1/4 position of the plate thickness in the thickness direction from the surface) to 1/2 position of the plate thickness, and use the microstructure photograph taken with an optical microscope Is determined by visual judgment, and the particle size of the ferrite is determined by image analysis. The particle size distribution of the ferrite grain size is obtained for each field of view, the standard deviation is calculated, and the value obtained by averaging the standard deviations of the 10 fields of view is taken as the standard deviation of the ferrite grain size. For image analysis, Olympus Corporation's image analysis software “Stream Essentials” was used.

所望の金属組織は、成分組成を調整し、熱間圧延工程での加熱温度、仕上げ圧延温度、最終スタンドの圧下率および巻取り温度を調整し、一次冷間圧延の圧下率を調整し、連続焼鈍工程での冷却速度を調整し、二次冷間圧延工程における圧下率を調整することで得ることができる。なお、製造条件の詳細については、後述する。   The desired metallographic structure is adjusted by adjusting the component composition, adjusting the heating temperature in the hot rolling process, the finishing rolling temperature, the rolling reduction and winding temperature of the final stand, adjusting the rolling reduction of the primary cold rolling, and continuously. It can be obtained by adjusting the cooling rate in the annealing process and adjusting the rolling reduction in the secondary cold rolling process. Details of the manufacturing conditions will be described later.

以上の成分組成および組織を有する鋼板では、例えば0.20mm以下の板厚であっても、高い強度、具体的には560MPa以上の降伏強度を確保することができる。
すなわち、本発明の鋼板には、例えば王冠に供する場合に、瓶の口にかしめた王冠が内圧によって外れないための、耐圧強度が求められる。従来用いられてきた王冠用鋼板の板厚は0.22mm以上であったが、板厚を0.20mm以下、特に0.18mm以下とする薄肉化にあたっては、従来よりも高い強度が必要となる。鋼板の降伏強度が560MPa未満であると、上記のような薄肉化した王冠に十分な耐圧強度を付与することが不可能である。そのためには、降伏強度は560MPa以上である必要がある。さらに十分な耐圧強度を確保するためには降伏強度は600MPa以上が好ましい。降伏強度が高すぎると王冠成形時に王冠高さが低くなり王冠形状が不均一となるため、圧延方向の降伏強度は700MPa以下が好ましい。より好ましくは600MPa以上680MPa以下である。
With a steel sheet having the above component composition and structure, for example, a high strength, specifically a yield strength of 560 MPa or more, can be ensured even with a thickness of 0.20 mm or less.
In other words, the steel plate of the present invention is required to have a pressure strength that prevents the crown crimped on the mouth of the bottle from being removed by the internal pressure when the steel plate is used, for example. The steel plate for crowns that has been used conventionally has a thickness of 0.22 mm or more, but in order to reduce the thickness to 0.20 mm or less, particularly 0.18 mm or less, higher strength is required than before. . When the yield strength of the steel sheet is less than 560 MPa, it is impossible to give sufficient pressure resistance to the thin crown as described above. For that purpose, the yield strength needs to be 560 MPa or more. Furthermore, in order to ensure sufficient pressure resistance, the yield strength is preferably 600 MPa or more. If the yield strength is too high, the crown height becomes low at the time of crown molding and the crown shape becomes non-uniform, so the yield strength in the rolling direction is preferably 700 MPa or less. More preferably, it is 600 MPa or more and 680 MPa or less.

なお、降伏強度は「JIS Z 2241」に示される金属材料引張試験方法により測定できる。   The yield strength can be measured by a metal material tensile test method shown in “JIS Z 2241”.

次に、本発明に係る鋼板の製造方法について説明する。
本発明の鋼板は、上記成分組成からなる鋼素材(鋼スラブ)を、1200℃以上で加熱し、仕上げ圧延温度が870℃以上で、最終スタンドの圧下率が10%以上とし、550〜750℃の温度範囲内で巻取る熱間圧延工程と、前記熱間圧延後に酸洗する酸洗工程と、前記酸洗工程後に、圧下率が88%以上で冷間圧延する一次冷間圧延工程と、前記一次冷間圧延後に、均熱温度が660〜760℃の温度域にある保持時間を60秒以下とし、10℃/s以上の平均冷却速度で450℃以下の温度域まで冷却し、5℃/s以上の平均冷却速度で140℃以下の温度域まで冷却する連続焼鈍工程と、10%以上40%以下の圧下率で二次冷間圧延を行うことで製造される。
Next, the manufacturing method of the steel plate which concerns on this invention is demonstrated.
In the steel sheet of the present invention, a steel material (steel slab) having the above composition is heated at 1200 ° C. or higher, the finish rolling temperature is 870 ° C. or higher, and the rolling reduction of the final stand is 10% or higher, 550 to 750 ° C. A hot rolling step of winding within the temperature range, a pickling step of pickling after the hot rolling, a primary cold rolling step of cold rolling at a rolling reduction of 88% or more after the pickling step, After the primary cold rolling, the holding time in the temperature range of 660 to 760 ° C. is 60 seconds or less, and the temperature is cooled to 450 ° C. or less at an average cooling rate of 10 ° C./s or more. It is manufactured by carrying out secondary cold rolling at a continuous annealing step of cooling to a temperature range of 140 ° C. or less at an average cooling rate of at least / s and at a reduction rate of 10% or more and 40% or less.

なお、以下の説明において、温度の規定は鋼板の表面温度を基準とする。また、平均冷却速度は表面温度を基に計算して得られた値とする。例えば、均熱温度から450℃以下の温度域までの平均冷却速度は((均熱温度−(450℃以下の温度域))/均熱温度から(450℃以下の温度域)までの冷却時間)で表される。なお、上式における「450℃以下の温度域」とは該温度域にある冷却停止温度を意味している。   In the following description, the temperature is defined based on the surface temperature of the steel sheet. The average cooling rate is a value obtained by calculation based on the surface temperature. For example, the average cooling rate from the soaking temperature to a temperature range of 450 ° C. or less is ((soaking temperature− (temperature range of 450 ° C. or less)) / cooling time from the soaking temperature to a temperature range of 450 ° C. or less) ). The “temperature range of 450 ° C. or lower” in the above equation means a cooling stop temperature in the temperature range.

本発明に係る鋼板を製造する際は、転炉などを用いた公知の方法により、溶鋼を上記の化学成分に調整し、その後、例えば連続鋳造法によるスラブとして、鋼素材とする。   When manufacturing the steel plate according to the present invention, the molten steel is adjusted to the above chemical components by a known method using a converter or the like, and then, for example, a steel material is formed as a slab by a continuous casting method.

(鋼素材加熱温度:1200℃以上)
熱間圧延工程の鋼素材の加熱温度は1200℃以上とする。該加熱温度が1200℃未満であると、本発明において強度を確保するために必要な固溶N量が低減し、強度が低下するため、1200℃以上とする。なお、本発明の鋼組成では鋼中Nは主にAlNとして存在すると考えられるため、Nの総量(Ntotal)からAlNとして存在するN量(NasAlN)を差し引いた(Ntotal−(NasAlN))を固溶N量とみなした。鋼板の圧延方向の降伏強度を560MPa以上とするためには、固溶N量は0.0071%以上であることが好ましく、鋼素材加熱温度を1200℃以上とすることで確保することができる。より好ましい固溶N量は、0.0090%以上であり、そのためには鋼素材加熱温度を1220℃以上とするとよい。鋼素材加熱温度は1300℃超としても効果が飽和するため、1300℃以下が好ましい。
(Steel material heating temperature: 1200 ° C or higher)
The heating temperature of the steel material in the hot rolling process is set to 1200 ° C. or higher. When the heating temperature is less than 1200 ° C., the amount of solute N necessary for securing strength in the present invention is reduced and the strength is lowered, so that the heating temperature is 1200 ° C. or higher. In the steel composition of the present invention, it is considered that N in the steel mainly exists as AlN. Therefore, the total amount of N (Ntotal) minus the amount of N existing as AlN (NasAlN) is subtracted (Ntotal- (NasAlN)). The amount of dissolved N was considered. In order to set the yield strength in the rolling direction of the steel sheet to 560 MPa or more, the solute N amount is preferably 0.0071% or more, and can be ensured by setting the steel material heating temperature to 1200 ° C. or more. A more preferable amount of solute N is 0.0090% or more. For this purpose, the heating temperature of the steel material is preferably 1220 ° C. or more. Even if the steel material heating temperature exceeds 1300 ° C., the effect is saturated, so 1300 ° C. or less is preferable.

(仕上げ圧延温度:870℃以上)
熱間圧延工程の仕上げ温度が870℃未満となると、鋼板のフェライトの一部が細かくなり、フェライト粒径の標準偏差が7.0μm超となって成形性が悪化する。すると、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、仕上げ温度は、870℃以上とする。一方、必要以上に仕上げ圧延温度を高くすることは薄鋼板の製造を困難にする場合がある。具体的には、仕上げ圧延温度は870℃以上950℃以下の温度範囲内とすることが好ましい。
(Finishing rolling temperature: 870 ° C or higher)
When the finishing temperature in the hot rolling process is less than 870 ° C., a part of the ferrite of the steel sheet becomes fine, and the standard deviation of the ferrite grain size exceeds 7.0 μm and the formability deteriorates. Then, for example, when it is used for a crown, the crown shape becomes non-uniform, and when it is used for a DRD can, for example, it leads to a shape defect in which a wrinkle is generated in the flange portion at the time of DRD can molding. Accordingly, the finishing temperature is 870 ° C. or higher. On the other hand, raising the finish rolling temperature more than necessary may make it difficult to produce a thin steel sheet. Specifically, the finish rolling temperature is preferably in the temperature range of 870 ° C. or more and 950 ° C. or less.

(最終スタンドの圧下率:10%以上)
熱間圧延工程の最終スタンドの圧下率は10%以上とする。最終スタンドの圧下率が10%未満となると、鋼板のフェライトの一部が粗大化し、フェライトの標準偏差が7.0μm超となって成形性が悪化する。すると、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、最終スタンドの圧下率は10%以上とする。フェライト粒径の標準偏差を小さくするには最終スタンドの圧下率は12%以上とすることが好ましい。最終スタンドの圧下率の上限は、圧延荷重の観点で15%以下とすることが好ましい。
(Rolling ratio of final stand: 10% or more)
The rolling reduction of the final stand in the hot rolling process is 10% or more. When the rolling reduction of the final stand is less than 10%, a part of the ferrite of the steel sheet becomes coarse, and the standard deviation of the ferrite exceeds 7.0 μm, and the formability deteriorates. Then, for example, when it is used for a crown, the crown shape becomes non-uniform, and when it is used for a DRD can, for example, it leads to a shape defect in which a wrinkle is generated in the flange portion at the time of DRD can molding. Therefore, the rolling reduction of the final stand is 10% or more. In order to reduce the standard deviation of the ferrite grain size, the rolling reduction of the final stand is preferably 12% or more. The upper limit of the rolling reduction of the final stand is preferably 15% or less from the viewpoint of rolling load.

(巻取温度:550〜750℃)
熱間圧延工程の巻取温度が550℃未満となると、鋼板のフェライトの一部が細かくなり、フェライト粒径の標準偏差が7.0μm超となって成形性が悪化する。すると、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、巻取温度は550℃以上とする。一方、巻取温度が750℃より高くなると、鋼板のフェライトの一部が粗大化し、フェライトの標準偏差が7.0μm超となって、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、巻取温度は750℃以下とする。好ましくは600℃以上700℃以下である。
(Winding temperature: 550-750 ° C.)
When the coiling temperature in the hot rolling process is less than 550 ° C., a part of the ferrite of the steel sheet becomes fine, the standard deviation of the ferrite grain size exceeds 7.0 μm, and the formability deteriorates. Then, for example, when it is used for a crown, the crown shape becomes non-uniform, and when it is used for a DRD can, for example, it leads to a shape defect in which a wrinkle is generated in the flange portion at the time of DRD can molding. Accordingly, the winding temperature is set to 550 ° C. or higher. On the other hand, when the coiling temperature is higher than 750 ° C., a part of the ferrite of the steel sheet becomes coarse, and the standard deviation of the ferrite exceeds 7.0 μm. For example, when used for a crown, the crown shape becomes non-uniform. For example, when it is used for a DRD can, it causes a shape defect in which a wrinkle is generated in the flange portion when the DRD can is formed. Therefore, the coiling temperature is 750 ° C. or lower. Preferably they are 600 degreeC or more and 700 degrees C or less.

.(酸洗)
その後、酸洗を行うことが好ましい。酸洗は、表層スケールが除去できればよく、特に条件を限定する必要はない。
. (Pickling)
Thereafter, pickling is preferably performed. The pickling is not particularly limited as long as the surface scale can be removed.

次に、冷間圧延は、焼鈍を挟む2回に分けて行う。
(一次冷間圧延圧下率:88%以上)
まず、一次冷間圧延工程の圧下率は88%以上とする。一次冷間圧延工程の圧下率は88%未満となると冷間圧延で鋼板に付与されるひずみが低下するため、連続焼鈍工程における再結晶が不均一となり、フェライトの標準偏差が7.0μm超となって成形性が悪化する。すると、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、一次冷間圧延工程の圧下率は88%以上とする。より好ましくは89〜94%とする。
Next, the cold rolling is performed in two steps with the annealing interposed therebetween.
(Primary cold rolling reduction: 88% or more)
First, the rolling reduction in the primary cold rolling process is 88% or more. When the rolling reduction in the primary cold rolling process is less than 88%, the strain imparted to the steel sheet by cold rolling decreases, so recrystallization in the continuous annealing process becomes non-uniform and the standard deviation of ferrite is over 7.0 μm. As a result, the moldability deteriorates. Then, for example, when it is used for a crown, the crown shape becomes non-uniform, and when it is used for a DRD can, for example, it leads to a shape defect in which a wrinkle is generated in the flange portion at the time of DRD can molding. Therefore, the rolling reduction in the primary cold rolling process is set to 88% or more. More preferably, it is 89 to 94%.

一次冷間圧延後の焼鈍工程では、660〜760℃の温度域に60秒以下で保持したのち、10℃/s以上の平均冷却速度で450℃以下の温度域まで冷却する前段冷却と、次いで5℃/s以上の平均冷却速度で140℃以下の温度域まで冷却する後段冷却と、を行う。
(均熱温度:660〜760℃)
すなわち、連続焼鈍工程における均熱温度は、660〜760℃の温度で行う。均熱温度を760℃超とすると、連続焼鈍においてヒートバックルなどの通板トラブルが発生しやすくなり、好ましくない。また、鋼板のフェライト粒径が一部粗大化し、フェライトの標準偏差が7.0μm超となり、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねくことになる。一方、焼鈍温度が660℃未満であると、再結晶が不完全となり、鋼板のフェライト粒径が一部細かくなり、フェライト粒径の標準偏差が7.0μm超となり、例えば王冠用に供した場合に、王冠形状が不均一となり、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、均熱温度は、660〜760℃の温度で行うこととする。好ましくは、680〜730℃の温度で行う。
In the annealing step after the primary cold rolling, after maintaining in the temperature range of 660 to 760 ° C. for 60 seconds or less, cooling to the temperature range of 450 ° C. or less at an average cooling rate of 10 ° C./s or more, then The latter stage cooling which cools to the temperature range of 140 degrees C or less with an average cooling rate of 5 degrees C / s or more is performed.
(Soaking temperature: 660-760 ° C.)
That is, the soaking temperature in the continuous annealing step is 660 to 760 ° C. When the soaking temperature is higher than 760 ° C., it is easy to cause troubles such as a heat buckle during continuous annealing, which is not preferable. In addition, the ferrite grain size of the steel sheet is partially coarsened, the standard deviation of the ferrite is over 7.0 μm, for example, when used for a crown, the crown shape becomes non-uniform, for example, when used for a DRD can, This leads to a shape defect in which wrinkles are generated in the flange part during DRD can molding. On the other hand, if the annealing temperature is less than 660 ° C., the recrystallization becomes incomplete, the ferrite grain size of the steel sheet becomes partly fine, and the standard deviation of the ferrite grain size exceeds 7.0 μm. In addition, the crown shape becomes non-uniform, and when used for a DRD can, for example, it leads to a shape defect that causes wrinkles in the flange portion when the DRD can is formed. Accordingly, the soaking temperature is 660 to 760 ° C. Preferably, it is performed at a temperature of 680 to 730 ° C.

均熱温度が660〜760℃の温度域にある保持時間は60秒以下とする。保持時間が60秒を超えると、鋼板に含有するCがフェライト粒界へ偏析して、連続焼鈍工程での冷却過程で炭化物として析出し、鋼板強度に寄与する固溶C量が低減し、降伏強度が低下する。さらに、鋼板を例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。従って、均熱温度が660〜760℃の温度域にある保持時間は60秒以下とする。なお、保持時間が5秒未満となると、均熱帯のロールを鋼板が通板する際の安定性が損なわれるため、好ましくは保持時間を5秒以上とする。   The holding time when the soaking temperature is in the temperature range of 660 to 760 ° C. is 60 seconds or less. When the holding time exceeds 60 seconds, C contained in the steel sheet segregates to the ferrite grain boundary, precipitates as carbides in the cooling process in the continuous annealing process, reduces the amount of solute C contributing to the steel sheet strength, and yield. Strength decreases. Furthermore, when a steel plate is used for, for example, a DRD can, a shape defect that causes wrinkles in the flange portion at the time of forming the DRD can results. Therefore, the holding time when the soaking temperature is in the temperature range of 660 to 760 ° C. is set to 60 seconds or less. When the holding time is less than 5 seconds, the stability when the steel plate passes through the soaking roll is impaired, and therefore the holding time is preferably 5 seconds or more.

(前段冷却:10℃/s以上の平均冷却速度で450℃以下まで冷却)
前記均熱後、10℃/s以上の平均冷却速度で450℃以下の温度域まで冷却する。平均冷却速度が10℃/s未満となると、冷却中に炭化物析出が促進されて、鋼板強度に寄与する固溶C量が低減し、降伏強度が低下する。さらに、鋼板を例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。なお、平均冷却速度が50℃/s超となると上記の効果が飽和するため、平均冷却速度は50℃/s以下とすることが好ましい。
また、均熱後の前段冷却における冷却停止温度が450℃超となると、前段冷却後に炭化物析出が促進されて、鋼板強度に寄与する固溶C量が低減し、降伏強度が低下する。さらに、鋼板を例えばDRD缶用に供した場合、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。なお、均熱後の前段冷却における冷却停止温度が300℃未満となると、炭化物析出抑制効果が飽和するばかりか、通板する際の鋼板形状が劣化して鋼板が均一に冷却できなくなり、例えば王冠用に供した場合に、王冠形状が不均一となり、さらに、例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねくため、均熱後の冷却停止温度は300℃以上とすることが好ましい。
(Pre-cooling: Cooling to 450 ° C or less at an average cooling rate of 10 ° C / s or more)
After the soaking, it is cooled to a temperature range of 450 ° C. or lower at an average cooling rate of 10 ° C./s or higher. When the average cooling rate is less than 10 ° C./s, carbide precipitation is promoted during cooling, the amount of solute C contributing to the steel plate strength is reduced, and the yield strength is reduced. Furthermore, when a steel plate is used for, for example, a DRD can, a shape defect that causes wrinkles in the flange portion at the time of forming the DRD can results. In addition, since said effect will be saturated when an average cooling rate exceeds 50 degrees C / s, it is preferable that an average cooling rate shall be 50 degrees C / s or less.
Moreover, when the cooling stop temperature in the former stage cooling after soaking exceeds 450 ° C., carbide precipitation is promoted after the former stage cooling, the amount of solute C contributing to the steel sheet strength is reduced, and the yield strength is lowered. Furthermore, when a steel plate is used for, for example, a DRD can, a shape defect in which wrinkles are generated in the flange portion when the DRD can is formed is caused. In addition, when the cooling stop temperature in the pre-cooling after soaking is less than 300 ° C., not only the carbide precipitation suppression effect is saturated, but the steel plate shape deteriorates when passing and the steel plate cannot be cooled uniformly, for example, crown For example, when used for DRD cans, the crown stop shape is uneven. It is preferable to set it to 300 degreeC or more.

(後段冷却:5℃/s以上の平均冷却速度で140℃以下まで)
前段冷却後の後段冷却では、5℃/s以上の平均冷却速度で前段冷却時の冷却停止温度から140℃以下の温度域まで冷却する。平均冷却速度が5℃/s未満となると、鋼板強度に寄与する固溶C量が低減し降伏強度が低下する。さらに、鋼板を例えばDRD缶用に供した場合に、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。なお、平均冷却速度が30℃/s超となると、効果が飽和するばかりか、冷却設備に過剰なコストが発生するため後段冷却での平均冷却速度は30℃/s以下が好ましい。より好ましくは25℃/s以下である。
後段冷却では140℃以下まで冷却する。140℃超となると、鋼板強度に寄与する固溶C量が低減し、降伏強度が低下する。さらに、鋼板を例えばDRD缶用に供した場合、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。なお、冷却停止温度が100℃未満となると効果が飽和するばかりか、冷却設備に過剰なコストが発生するため100℃以上が好ましい。より好ましくは120℃以上である。
(Second-stage cooling: up to 140 ° C or less at an average cooling rate of 5 ° C / s or more)
In the latter stage cooling after the former stage cooling, the cooling is performed at an average cooling rate of 5 ° C./s or more from the cooling stop temperature at the former stage cooling to a temperature range of 140 ° C. or less. When the average cooling rate is less than 5 ° C./s, the amount of solute C contributing to the steel plate strength is reduced, and the yield strength is lowered. Furthermore, when a steel plate is used for, for example, a DRD can, a shape defect that causes wrinkles in the flange portion at the time of forming the DRD can results. When the average cooling rate exceeds 30 ° C./s, not only the effect is saturated, but excessive costs are generated in the cooling equipment, so that the average cooling rate in the subsequent cooling is preferably 30 ° C./s or less. More preferably, it is 25 ° C./s or less.
In the latter stage cooling, it is cooled to 140 ° C. or lower. If it exceeds 140 ° C., the amount of solute C that contributes to the strength of the steel sheet decreases, and the yield strength decreases. Furthermore, when a steel plate is used for, for example, a DRD can, a shape defect in which wrinkles are generated in the flange portion when the DRD can is formed is caused. Note that when the cooling stop temperature is less than 100 ° C., the effect is saturated, and an excessive cost is generated in the cooling facility. More preferably, it is 120 ° C. or higher.

(二次冷間圧延圧下率:10%以上40%以下)
本発明の鋼板は、焼鈍後の二回目の冷間圧延により高い降伏強度を得ることができる。すなわち、二次冷間圧延の圧下率が10%未満であると、十分な降伏強度が得られない。また、二次冷間圧延の圧下率が40%を超えると、例えば鋼板を王冠用に供した場合に王冠形状の均一性を損なう。さらに、例えばDRD缶用に供した場合、DRD缶成形時にフランジ部にしわが発生する形状不良をまねく。よって、二次冷間圧延の圧下率は10%以上40%以下とすることが好ましい。より好ましくは、二次冷間圧延の圧下率は15%超35%以下である。
(Secondary cold rolling reduction: 10% to 40%)
The steel sheet of the present invention can obtain high yield strength by the second cold rolling after annealing. That is, when the rolling reduction of secondary cold rolling is less than 10%, sufficient yield strength cannot be obtained. On the other hand, when the rolling reduction of secondary cold rolling exceeds 40%, for example, when the steel sheet is used for a crown, the uniformity of the crown shape is impaired. Furthermore, for example, when it is used for a DRD can, it causes a shape defect in which a wrinkle is generated in the flange portion when the DRD can is formed. Therefore, it is preferable that the rolling reduction of secondary cold rolling shall be 10% or more and 40% or less. More preferably, the rolling reduction of secondary cold rolling is more than 15% and 35% or less.

上記のようにして得た冷延鋼板は、その後、必要に応じて、鋼板表面に、例えば電気めっきにより、錫めっき、クロムめっき、ニッケルめっき等のめっき処理を施してめっき層を形成し、めっき鋼板として使用に供してもよい。なお、めっき等の表面処理の膜厚は、板厚に対して十分に小さいので、鋼板の機械特性への影響は無視できるレベルである。   The cold-rolled steel sheet obtained as described above is then subjected to plating treatment such as tin plating, chromium plating, nickel plating, etc., for example, by electroplating on the surface of the steel sheet, if necessary, to form a plating layer. You may use for a steel plate. Since the film thickness of the surface treatment such as plating is sufficiently small with respect to the plate thickness, the influence on the mechanical properties of the steel plate is negligible.

以上、説明したように、本発明の鋼板は、薄肉化しても十分な強度および優れた材質均一性を備えることができる。従って、本発明の鋼板は、特に王冠あるいはDRD缶の素材として最適である。
また、本発明の王冠は、上述した鋼板を用いて成形されるものである。王冠は、主に瓶の口を塞ぐ円盤状の部分と、その周囲に設けられた襞状の部分とから構成される。本発明の王冠は、本発明の鋼板を円形のブランクに打ち抜いた後、プレス成形により成形することができる。本発明の王冠は、十分な降伏強度を有し、かつ、材質均一性に優れた鋼板から製造されるので、薄肉化しても王冠としての耐圧強度に優れており、かつ王冠の外径および高さの均一性が優れているため、王冠製造工程での歩留りが向上し、王冠製造に伴う廃棄物の排出量を減らす効果を有する。
As described above, the steel sheet of the present invention can have sufficient strength and excellent material uniformity even if it is thinned. Therefore, the steel sheet of the present invention is particularly suitable as a material for crowns or DRD cans.
The crown of the present invention is formed using the steel plate described above. The crown is mainly composed of a disk-shaped part that closes the mouth of the bottle and a bowl-shaped part provided around the disk-shaped part. The crown of the present invention can be formed by press molding after punching the steel plate of the present invention into a circular blank. Since the crown of the present invention is manufactured from a steel sheet having sufficient yield strength and excellent material uniformity, it has excellent pressure resistance as a crown even when it is thinned, and has an outer diameter and high crown. Since the uniformity of the height is excellent, the yield in the crown manufacturing process is improved, and the amount of waste generated by the crown manufacturing is reduced.

同様に、本発明のDRD缶は、上述した鋼板を用いて成形されるものである。DRD缶は、本発明の鋼板を円形のブランクに打ち抜いた後、絞り加工および再絞り加工を施すことにより成形することができる。本発明の鋼板を素材とするDRD缶は、形状が均一で製品規格から外れることがないため、DRD缶製造工程での歩留まりが向上し、DRD缶製造に伴う廃棄物の排出量を減らす効果も有する。   Similarly, the DRD can of the present invention is formed using the steel plate described above. The DRD can can be formed by punching the steel sheet of the present invention into a circular blank and then performing drawing and redrawing. Since the DRD can made of the steel plate of the present invention has a uniform shape and does not deviate from the product standard, the yield in the DRD can manufacturing process is improved, and the amount of waste generated in the DRD can manufacturing is reduced. Have.

表1に示す成分組成を含有し、残部はFeおよび不可避的不純物からなる鋼を転炉で溶製し、連続鋳造することにより鋼スラブを得た。ここで得られた鋼スラブに対して、表2に示すスラブ加熱温度、仕上圧延温度、巻取り温度での熱間圧延を施した。この熱間圧延後には酸洗を行った。次いで、表2に示す圧下率で一次冷間圧延を行い、表2に示す連続焼鈍条件にて連続焼鈍し、引き続き、表2に示す圧下率で二次冷間圧延を施した。得られた鋼板に電解クロム酸処理を連続的に施して、ティンフリースチールを得た。   A steel slab was obtained by containing the component composition shown in Table 1, with the balance being made of Fe and unavoidable impurities in a converter and continuously cast. The steel slab obtained here was subjected to hot rolling at the slab heating temperature, finish rolling temperature, and winding temperature shown in Table 2. After this hot rolling, pickling was performed. Next, primary cold rolling was performed at the rolling reduction shown in Table 2, and continuous annealing was performed under the continuous annealing conditions shown in Table 2, followed by secondary cold rolling at the rolling reduction shown in Table 2. The obtained steel sheet was continuously subjected to electrolytic chromic acid treatment to obtain tin-free steel.

Figure 0006468404
Figure 0006468404

以上にしたがって得られた鋼板に対して、210℃および15分の塗装焼付け相当の熱処理を行った後、引張試験を行った。引張試験は、JIS5号サイズの引張試験片を用いて、「JIS Z 2241」に従って行い、圧延方向の降伏強度を測定した。なお、この塗装焼付け相当の熱処理は、該熱処理前の鋼板材質に何ら影響を与えるものではない。   The steel plate obtained in accordance with the above was subjected to a heat treatment equivalent to 210 ° C. and 15 minutes of paint baking, and then subjected to a tensile test. The tensile test was performed according to “JIS Z 2241” using a JIS No. 5 size tensile test piece, and the yield strength in the rolling direction was measured. The heat treatment equivalent to this paint baking does not affect the steel plate material before the heat treatment.

得られた鋼板を用いて王冠に成形し、王冠成形性を評価した。すなわち、直径37mmの円形ブランクを使用し、プレス加工により各鋼板について各20個(N=20)の王冠を成形した。王冠の高さ(王冠天面からスカート下端までの距離)はマイクロメータを用いて測定し、N=20の王冠高さの標準偏差が0.09mm以下を王冠形状が優れる、0.09mm超を王冠形状が劣るとした。得られた結果を表2に示す。   The obtained steel plate was formed into a crown, and the crown formability was evaluated. That is, using a circular blank having a diameter of 37 mm, 20 crowns (N = 20) were formed for each steel plate by pressing. The height of the crown (distance from the top of the crown to the bottom of the skirt) is measured using a micrometer, and the standard deviation of the crown height of N = 20 is 0.09 mm or less, the crown shape is excellent, more than 0.09 mm The crown shape is inferior. The obtained results are shown in Table 2.

さらに、得られた鋼板を用いて、210℃、15分の塗装焼付け相当の熱処理を行った後、DRD缶に成形し、DRD缶成形性を評価した。すなわち、直径158mmの円形ブランクを使用し、絞り加工および再絞り加工を施し、内径82.8mm、フランジ径102mmのDRD缶を成形し、DRD缶成形性を評価した。評価は、目視でフランジ部に微細なしわが3箇所以上見られるサンプルを×、フランジ部の微細なしわが2箇所以下であるサンプルを○とした。この評価結果を表2に示す。   Further, the obtained steel sheet was subjected to a heat treatment equivalent to coating baking at 210 ° C. for 15 minutes, then formed into a DRD can, and the DRD can formability was evaluated. That is, using a circular blank having a diameter of 158 mm, drawing and redrawing were performed, a DRD can having an inner diameter of 82.8 mm and a flange diameter of 102 mm was formed, and DRD can moldability was evaluated. In the evaluation, a sample in which three or more fine wrinkles are visually observed in the flange portion was evaluated as “x”, and a sample in which the fine wrinkles in the flange portion were two or less locations was evaluated as “good”. The evaluation results are shown in Table 2.

Figure 0006468404
Figure 0006468404

表2より、本発明例であるNo.1〜22の鋼板は、圧延方向の降伏強度が560MPa以上、かつ王冠高さの標準偏差が0.09mm以下であり、王冠成形性は良好であることがわかる。さらに、DRD缶成形におけるしわの発生数は2箇所以下であり、DRD缶成形性も良好であった。   From Table 2, the steel sheets of Nos. 1 to 22 as examples of the present invention have a yield strength in the rolling direction of 560 MPa or more, a standard deviation of the crown height of 0.09 mm or less, and a good crown formability. I understand. Furthermore, the number of wrinkles generated in DRD can molding was 2 or less, and the DRD can moldability was also good.

一方、比較例であるNo.23〜25の鋼板は、Cの含有量が多すぎるため、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。No.26〜28の鋼板は、Cの含有量が少なすぎるため、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化することが分かった。No.29の鋼板は、Mnの含有量が多すぎるため、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。No.30の鋼板は、Alの含有量が多すぎるため、AlNの形成が増加して、固溶Nとして鋼板強度に寄与するN量が低減し、鋼板強度が低下することが分かった。またDRD缶成形性も劣化した。No.31の鋼板は、Alの含有量が少なすぎるため、脱酸剤としての効果が不十分であり、凝固欠陥の発生を招くとともに製鋼コストが増大する。また、焼鈍でのフェライトの再結晶時に適切な量のAlNを確保できないため、焼鈍後のフェライト粒径の標準偏差が大きくなり、二次冷間圧延後の鋼板のフェライト粒径が粗大となり、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。No.32〜34の鋼板は、Nの含有量が多すぎるため、二次冷間圧延後の鋼板のフェライト粒径が微細となり、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。No.35〜37の鋼板は、Nの含有量が少なすぎるため、鋼板のフェライト粒径が粗大となり、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化するとともに固溶Nとして鋼板強度に寄与するN量が低減し、鋼板強度が低下することが分かった。また、No.38の鋼板は、Pの含有量が多すぎるため、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。No.39の鋼板は、Siの含有量が多すぎるため、フェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。   On the other hand, the steel plates No. 23 to 25, which are comparative examples, have too much C, so the standard deviation of ferrite grain size is over 7.0 μm, and the standard deviation of crown height is over 0.09 mm. It was found that moldability deteriorates and DRD can moldability also deteriorates. Steel plates No. 26 to 28 have too little C content, so the standard deviation of ferrite grain size exceeds 7.0 μm, the standard deviation of crown height exceeds 0.09 mm, and the crown formability deteriorates. I understood. The No. 29 steel plate contains too much Mn, so the standard deviation of ferrite grain size exceeds 7.0 μm, the standard deviation of crown height exceeds 0.09 mm, and the crown formability deteriorates. It was found that can moldability also deteriorated. It was found that the No. 30 steel sheet contained too much Al, so the formation of AlN was increased, the amount of N contributing to the steel sheet strength as solute N was reduced, and the steel sheet strength was reduced. The DRD can moldability also deteriorated. The steel plate of No. 31 has too little Al content, so that the effect as a deoxidizer is insufficient, causing solidification defects and increasing the steelmaking cost. In addition, since an appropriate amount of AlN cannot be secured during recrystallization of ferrite during annealing, the standard deviation of ferrite grain size after annealing becomes large, and the ferrite grain size of the steel sheet after secondary cold rolling becomes coarse. It was found that the standard deviation of the particle size exceeded 7.0 μm, the standard deviation of the crown height exceeded 0.09 mm, the crown moldability deteriorated, and the DRD can moldability deteriorated. Steel plates No. 32-34 have too much N content, so the ferrite grain size of the steel sheet after the secondary cold rolling becomes fine, and the standard deviation of the ferrite grain size exceeds 7.0 μm, and the crown height It was found that the standard deviation of the above exceeded 0.09 mm, the crown moldability deteriorated, and the DRD can moldability also deteriorated. Steel plates No. 35 to 37 have too little N content, so the ferrite grain size of the steel sheet is coarse, the standard deviation of ferrite grain size is over 7.0 μm, and the standard deviation of crown height is 0.09 mm. It has been found that the crown formability deteriorates, the DRD can formability deteriorates, and the amount of N that contributes to the steel sheet strength as solute N decreases and the steel sheet strength decreases. In addition, the No. 38 steel plate has too much P content, so the standard deviation of the ferrite grain size exceeds 7.0 μm, the standard deviation of the crown height exceeds 0.09 mm, and the crown formability deteriorates. Moreover, it turned out that DRD can moldability also deteriorates. The No. 39 steel sheet contains too much Si, so the standard deviation of ferrite grain size exceeds 7.0 μm, the standard deviation of crown height exceeds 0.09 mm, and the crown formability deteriorates. It was found that can moldability also deteriorated.

表1に示した鋼No.5,9,18,21,28,29,31の成分組成を含有し、残部はFeおよび不可避的不純物からなる鋼を転炉で溶製し、連続鋳造することにより鋼スラブを得た。ここで得られた鋼スラブに対して、表3に示すスラブ加熱温度、仕上圧延温度、巻取温度での熱間圧延を施した。熱間圧延後には酸洗を行った。次いで、表3に示す圧下率で一次冷間圧延を行い、表3に示す均熱保持温度、均熱保持時間、前段冷却平均速度、前段冷却停止温度、後段冷却平均速度、後段冷却停止温度で連続焼鈍し、引き続き、表3に示す圧下率で二次冷間圧延を施した。得られた鋼板に電解クロム酸処理を連続的に施して、ティンフリースチールを得た。   Steel No. shown in Table 1 Steel slabs were obtained by containing a component composition of 5, 9, 18, 21, 28, 29, and 31 with the balance being made of Fe and unavoidable impurities in a converter and continuously cast. The steel slab obtained here was hot-rolled at the slab heating temperature, finish rolling temperature, and coiling temperature shown in Table 3. After hot rolling, pickling was performed. Next, primary cold rolling is performed at the rolling reduction shown in Table 3, and the soaking temperature, soaking time, pre-cooling average speed, pre-cooling cooling stop temperature, post-cooling cooling average speed, and post-cooling cooling stop temperature shown in Table 3 are used. Continuous annealing was performed, followed by secondary cold rolling at the rolling reduction shown in Table 3. The obtained steel sheet was continuously subjected to electrolytic chromic acid treatment to obtain tin-free steel.

以上により得られた鋼板に対して、前述と同様の方法で引張試験を行うとともに、王冠成形性およびDRD缶成形性の評価を行った。得られた結果を表3に示す。   The steel plate obtained as described above was subjected to a tensile test by the same method as described above, and was evaluated for crown formability and DRD can formability. The obtained results are shown in Table 3.

Figure 0006468404
Figure 0006468404

表3より、本発明例である鋼板No.40、43、45、47、48、52〜55、58、59、63、64、66、69、70、71の鋼板は、圧延方向の降伏強度が560MPa以上と高く、かつ王冠高さの標準偏差が0.09mm以下であり、王冠成形性、DRD缶成形性が良好であった。
一方、比較例である鋼板No.41、49、50、56、61、68、72の鋼板は、スラブ加熱温度、均熱保持時間、前段冷却平均速度、二次冷間圧下率、後段冷却平均速度、前段冷却停止温度、後段冷却停止温度が本発明範囲を外れるため、圧延方向の降伏強度が低下することが分かった。比較例である鋼板No.62の鋼板は、二次冷間圧下率が高すぎるため、鋼板の異方性が大きくなり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。比較例である鋼板No.42、44、46、51、57、60、65、67、73、74の鋼板は、スラブ加熱温度、熱間圧延の最終スタンド圧下率、巻取温度、一次冷間圧延率、均熱保持温度、前段冷却停止温度、後段冷却平均速度、後段冷却停止温度、二次冷間圧下率の何れかが本発明範囲外であるため、圧延方向の降伏強度が低下またはフェライト粒径の標準偏差が7.0μm超となり、王冠高さの標準偏差が0.09mm超となり王冠成形性が劣化し、またDRD缶成形性も劣化することが分かった。
From Table 3, steel plate No. which is an example of the present invention. Steel sheets of 40, 43, 45, 47, 48, 52-55, 58, 59, 63, 64, 66, 69, 70, 71 have a high yield strength in the rolling direction of 560 MPa or more and a standard crown height. The deviation was 0.09 mm or less, and the crown moldability and DRD can moldability were good.
On the other hand, steel plate No. which is a comparative example. Steel plates Nos. 41, 49, 50, 56, 61, 68, and 72 have a slab heating temperature, a soaking time, a pre-cooling average speed, a secondary cold reduction rate, a post-cooling average speed, a pre-cooling stop temperature, and a post-cooling. It was found that the yield strength in the rolling direction is lowered because the stop temperature is out of the range of the present invention. Steel plate No. which is a comparative example. The steel plate No. 62 has a secondary cold reduction ratio that is too high, so the anisotropy of the steel plate increases, the standard deviation of the crown height exceeds 0.09 mm, and the crown formability deteriorates, and the DRD can moldability also increases. It turns out that it deteriorates. Steel plate No. which is a comparative example. Steel plates of 42, 44, 46, 51, 57, 60, 65, 67, 73, 74 are slab heating temperature, final stand reduction ratio of hot rolling, winding temperature, primary cold rolling rate, soaking temperature. , Any one of the pre-stage cooling stop temperature, the post-stage cooling average speed, the post-stage cooling stop temperature, and the secondary cold rolling reduction is outside the range of the present invention, so that the yield strength in the rolling direction is reduced or the standard deviation of the ferrite grain size is 7 It was found that the standard deviation of the crown height exceeded 0.09 mm and the crown moldability deteriorated, and the DRD can moldability also deteriorated.

Claims (4)

質量%で、
C:0.0060%超0.0100%以下、
Si:0.05%以下、
Mn:0.05%以上0.60%以下、
P:0.050%以下、
S:0.050%以下、
Al:0.020%以上0.050%以下および
N:0.0070%以上0.0140%以下
を含有し、残部はFeおよび不可避的不純物の成分組成を有し、
板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下であり、
降伏強度が560MPa以上であり、
板厚が0.20mm以下である鋼板。
% By mass
C: more than 0.0060% and 0.0100% or less,
Si: 0.05% or less,
Mn: 0.05% or more and 0.60% or less,
P: 0.050% or less,
S: 0.050% or less,
Al: 0.020% or more and 0.050% or less and N: 0.0070% or more and 0.0140% or less, with the balance having a component composition of Fe and inevitable impurities,
Having a ferrite phase in the region from the depth of 1/4 of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7.0 μm or less,
Yield strength of Ri der more than 560MPa,
Der Ru steel plate below the plate thickness is 0.20mm.
質量%で、
C:0.0060%超0.0100%以下、
Si:0.05%以下、
Mn:0.05%以上0.60%以下、
P:0.050%以下、
S:0.050%以下、
Al:0.020%以上0.050%以下および
N:0.0070%以上0.0140%以下
を含有し、残部はFeおよび不可避的不純物の成分組成を有し、
板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下であり、
降伏強度が560MPa以上である鋼板からなる王冠。
% By mass
C: more than 0.0060% and 0.0100% or less,
Si: 0.05% or less,
Mn: 0.05% or more and 0.60% or less,
P: 0.050% or less,
S: 0.050% or less,
Al: 0.020% to 0.050% and
N: 0.0070% to 0.0140%
And the balance has a component composition of Fe and inevitable impurities,
Having a ferrite phase in the region from the depth of 1/4 of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7.0 μm or less,
A crown made of a steel plate with a yield strength of 560 MPa or more .
質量%で、
C:0.0060%超0.0100%以下、
Si:0.05%以下、
Mn:0.05%以上0.60%以下、
P:0.050%以下、
S:0.050%以下、
Al:0.020%以上0.050%以下および
N:0.0070%以上0.0140%以下
を含有し、残部はFeおよび不可避的不純物の成分組成を有し、
板厚の1/4の深さから板厚中心部までの領域にフェライト相を有し、該フェライト相におけるフェライト粒径の標準偏差が7.0μm以下であり、
降伏強度が560MPa以上である鋼板からなるDRD缶。
% By mass
C: more than 0.0060% and 0.0100% or less,
Si: 0.05% or less,
Mn: 0.05% or more and 0.60% or less,
P: 0.050% or less,
S: 0.050% or less,
Al: 0.020% to 0.050% and
N: 0.0070% to 0.0140%
And the balance has a component composition of Fe and inevitable impurities,
Having a ferrite phase in the region from the depth of 1/4 of the plate thickness to the center of the plate thickness, and the standard deviation of the ferrite grain size in the ferrite phase is 7.0 μm or less,
A DRD can made of a steel plate having a yield strength of 560 MPa or more .
請求項1に記載の鋼板の製造方法であり、
鋼素材を1200℃以上で加熱し、仕上げ圧延温度:870℃以上および最終スタンドの圧下率:10%以上の条件にて圧延を施して550〜750℃の温度範囲内で巻取る熱間圧延工程と、
前記熱間圧延後の熱延板に酸洗を行う酸洗工程と、
前記酸洗後の熱延板に、圧下率:88%以上の冷間圧延を行う一次冷間圧延工程と、
前記一次冷間圧延後の冷延板を、660〜760℃の温度域に60秒以下で保持したのち、10℃/s以上の平均冷却速度で450℃以下300℃以上の温度域まで冷却し、次いで5℃/s以上30℃/s以下の平均冷却速度で140℃以下の温度域まで冷却する焼鈍工程と、
前記焼鈍板に、10%以上40%以下の圧下率で冷間圧延を行う二次冷間圧延工程と、を有する鋼板の製造方法。
It is a manufacturing method of the steel plate according to claim 1 ,
A hot rolling process in which a steel material is heated at 1200 ° C. or higher, finished rolling temperature: 870 ° C. or higher and the rolling reduction of the final stand: 10% or higher, and wound in a temperature range of 550 to 750 ° C. When,
Pickling step of pickling the hot-rolled sheet after hot rolling;
A primary cold rolling step of performing cold rolling with a reduction ratio of 88% or more on the hot-rolled sheet after pickling,
The cold-rolled sheet after the first cold rolling is held in a temperature range of 660 to 760 ° C. for 60 seconds or less, and then cooled to a temperature range of 450 ° C. or less and 300 ° C. or more at an average cooling rate of 10 ° C./s or more. Then, an annealing step of cooling to a temperature range of 140 ° C. or less at an average cooling rate of 5 ° C./s or more and 30 ° C./s or less,
A secondary cold rolling step of performing cold rolling on the annealed plate at a rolling reduction of 10% to 40%.
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2013008457A1 (en) * 2011-07-12 2013-01-17 Jfeスチール株式会社 Steel sheet for can and process for producing same
JP2015199987A (en) * 2014-04-08 2015-11-12 新日鐵住金株式会社 HIGH STRENGTH HOT ROLLED STEEL SHEET EXCELLENT IN LOW TEMPERATURE TOUGHNESS AND UNIFORM ELONGATION AND HOLE EXPANSIBILITY AND HAVING TENSILE STRENGTH OF 780 MPa OR MORE AND PRODUCTION METHOD THEREFOR
WO2016104773A1 (en) * 2014-12-26 2016-06-30 新日鐵住金株式会社 Method for manufacturing steel sheet for bottle cap, and steel sheet for bottle cap

Family Cites Families (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS6057023B2 (en) 1979-07-25 1985-12-12 松下電工株式会社 Disconnection/short circuit detection circuit for smoke prevention control equipment
BR112013012558B1 (en) * 2010-11-22 2018-06-05 Nippon Steel & Sumitomo Metal Corporation STEELING PLATE OF AGING HARDENING AFTER EXCELLENT ENDURING IN AGING RESISTANCE AFTER FINISHING COOKING, AND METHOD FOR YOUR PRODUCTION
CN102766800A (en) * 2011-05-05 2012-11-07 上海梅山钢铁股份有限公司 Steel for hard tinplate bottle caps and production method thereof
KR101871735B1 (en) * 2014-02-25 2018-06-27 제이에프이 스틸 가부시키가이샤 Steel sheet for crown cap, method for manufacturing same, and crown cap
MX2016014060A (en) * 2014-04-30 2017-02-14 Jfe Steel Corp High-strength steel sheet and production method therefor.
CN107709598B (en) * 2015-06-30 2020-03-24 日本制铁株式会社 High-strength cold-rolled steel sheet, high-strength hot-dip galvanized steel sheet, and high-strength alloyed hot-dip galvanized steel sheet

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2013008457A1 (en) * 2011-07-12 2013-01-17 Jfeスチール株式会社 Steel sheet for can and process for producing same
JP2015199987A (en) * 2014-04-08 2015-11-12 新日鐵住金株式会社 HIGH STRENGTH HOT ROLLED STEEL SHEET EXCELLENT IN LOW TEMPERATURE TOUGHNESS AND UNIFORM ELONGATION AND HOLE EXPANSIBILITY AND HAVING TENSILE STRENGTH OF 780 MPa OR MORE AND PRODUCTION METHOD THEREFOR
WO2016104773A1 (en) * 2014-12-26 2016-06-30 新日鐵住金株式会社 Method for manufacturing steel sheet for bottle cap, and steel sheet for bottle cap

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