JPH07109527A - Production of extra thin steel sheet for welded can body, suitable for high speed welding - Google Patents
Production of extra thin steel sheet for welded can body, suitable for high speed weldingInfo
- Publication number
- JPH07109527A JPH07109527A JP25457093A JP25457093A JPH07109527A JP H07109527 A JPH07109527 A JP H07109527A JP 25457093 A JP25457093 A JP 25457093A JP 25457093 A JP25457093 A JP 25457093A JP H07109527 A JPH07109527 A JP H07109527A
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- rolling
- welding
- steel sheet
- Prior art date
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- Heat Treatment Of Sheet Steel (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は、圧延直交方向の延性劣
化がなく、板取り性が優れるとともに、高速溶接に適し
た溶接缶胴用極薄鋼板の製造法に関するものである。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing an ultra-thin steel sheet for a welding can body which is free from deterioration of ductility in the direction orthogonal to rolling, has excellent stripping properties and is suitable for high speed welding.
【0002】[0002]
【従来の技術】従来から、缶の接合は、半田付け、樹脂
接着、溶接などの方法で行われている。その中で、鋼板
歩留り向上のために、接合代を少なくできる溶接による
方法が、近年主流になりつつある。溶接による3ピース
缶の製造工程は一般に次のようなものである。2. Description of the Related Art Conventionally, cans are joined by methods such as soldering, resin bonding, and welding. Among them, in recent years, a welding method, which can reduce the joint margin, has been becoming mainstream in order to improve the yield of steel sheets. The manufacturing process of a three-piece can by welding is generally as follows.
【0003】幅約1メートル内外の大きな切板に、複数
の缶胴分に相当する塗装および印刷を施し、次にスリッ
ターで縦横に剪断して缶1個分の胴になる切板の小片
(これをブランクと呼ぶ)を切り出す。高速ワイヤーシ
ーム自動溶接機が、供給装置にセットされたこれらのブ
ランクを1枚ずつ取り込み、カール装置で曲げぐせを付
けた後、溶接されるべき端部を所定のオーバーラップ幅
となるように重ね合わせ、円盤状の回転電極で内面と外
面からラップ部を厚み方向に圧下すると同時に高周波電
流を流しながら、長さ方向に缶を進行させて、電気抵抗
溶接により接合する。このとき、最初に回転電極に咬み
込んだ溶接線端をリーディング・エッジ、最後に回転電
極を抜けた溶接線端をトレーリング・エッジと呼ぶ。ま
た溶接後の溶接線の幅をラップ幅と呼ぶ。ここまでの工
程で円筒形の缶胴が出来上がる。[0003] A large piece of cutting board with a width of about 1 meter inside and outside is painted and printed corresponding to a plurality of can bodies, and then a small piece of a cutting plate which is sheared vertically and horizontally by a slitter to form a body of one can ( This is called a blank). The high-speed wire seam automatic welding machine takes in these blanks set in the feeding device one by one, bends them with a curling device, and then stacks the ends to be welded to have a predetermined overlap width. Together, the wrap portion is pressed down in the thickness direction from the inner surface and the outer surface by the disk-shaped rotating electrode, and at the same time, the can is advanced in the length direction while flowing a high-frequency current and joined by electric resistance welding. At this time, the welding line end that first bites into the rotating electrode is called a leading edge, and the welding line end that finally leaves the rotating electrode is called a trailing edge. The width of the weld line after welding is called the lap width. A cylindrical can body is completed by the steps so far.
【0004】この溶接工程における品質は、溶接部が母
材以上の十分な強度を持ち、スプラッシュなどの有害な
副産物を出さず、リーディング・エッジからトレーリン
グ・エッジまでが均一なラップ幅で接合されることで決
まる。これらの溶接品質は、電流、電圧、周波数、回転
電極の圧下圧力、溶接前の設定ラップ幅、界面の接触電
気抵抗など多くの要因に複雑に依存すると言われてい
る。The quality of this welding process is that the welded part has sufficient strength more than the base metal, does not produce harmful by-products such as splash, and is joined with a uniform lap width from the leading edge to the trailing edge. Decided by It is said that these welding qualities are complicatedly dependent on many factors such as current, voltage, frequency, rolling electrode rolling pressure, set lap width before welding, and contact electric resistance at the interface.
【0005】次に、この円筒の直径より小さい直径の蓋
を取り付けるために、缶胴口部の直径を縮径するネック
加工を施す。これに続いて、ネック加工した缶胴に蓋を
つけるために、缶胴の端部に直径方向外側に向かって延
出するフランジ部を形成する工程があり、これをフラン
ジ加工と呼ぶ。フランジ加工の際、フランジ部に缶の内
容物が漏れる原因となる割れ、すなわちフランジ割れと
呼ばれる欠陥を生じることがある。このフランジ加工に
おいてフランジ割れの発生しにくい性能を、以下フラン
ジ加工性と称する。Next, in order to attach a lid having a diameter smaller than the diameter of the cylinder, neck processing is performed to reduce the diameter of the can body opening. Following this, there is a step of forming a flange portion extending outward in the diametrical direction at the end of the can body in order to attach a lid to the necked can body, which is called flanging. During flanging, cracks that cause the contents of the can to leak to the flange portion, that is, defects called flange cracks may occur. The performance in which flange cracking is unlikely to occur in this flanging is hereinafter referred to as flanging.
【0006】フランジ割れを生じる原因としては、溶接
による接合不良、鋼板の加工性不良、鋼板の介在物、溶
接部の硬化、溶接熱影響部の軟化などがある。一方、省
資源の観点から缶用素材の板厚は薄くなる傾向にあり、
板厚の薄手化に伴う缶強度の低下には鋼板の硬さを硬く
して対処している。このような薄鋼板としては、特開昭
51−131413号公報に見られるように、熱間圧延
鋼板を冷間圧延後、焼鈍し、再度冷間圧延を行う、いわ
ゆる2回冷間圧延方式により製造した鋼板、いわゆるダ
ブル・レデュースド鋼板(以下DR鋼板と略称する)が
ある。[0006] Causes of flange cracking include defective joining due to welding, poor workability of steel sheet, inclusions in the steel sheet, hardening of the welded portion, and softening of the weld heat affected zone. On the other hand, the plate thickness of the material for cans tends to be thin from the viewpoint of resource saving,
The hardness of the steel plate is made hard to deal with the reduction in the can strength due to the thinner plate thickness. As such a thin steel sheet, as seen in Japanese Patent Laid-Open No. 51-131413, a so-called two-time cold rolling method in which a hot-rolled steel sheet is cold-rolled, annealed, and cold-rolled again There is a manufactured steel plate, a so-called double reduced steel plate (hereinafter abbreviated as DR steel plate).
【0007】しかし、このDR鋼板は、2次冷間圧延歪
に起因する鋼板の加工性劣化および溶接熱影響部の軟化
が著しく、溶接後フランジ加工でフランジ割れを起こす
ことが多いという欠点がある。この問題を解決する方法
としては、特開昭58−164752号公報、特開昭5
9−89718号公報記載の方法などが提案されてい
る。しかし、これらの既存技術では、2次冷間圧延の圧
下率が約15%以上と大きいところから、フランジ加工
性を含む鋼板の材質特性の異方性が大きく、鋼板の圧延
方向が缶胴の軸方向に平行となるような板取り(以下、
この板取り方法をリバース法と称する)を行うと、溶接
後フランジ割れが多発するため、製缶業者は、必ず鋼板
の圧延方向が缶胴の軸方向に直角となるような板取り
(以下、この方法をノーマル法と称する)を行わなけれ
ばならないという制約を強いられる問題があった。さら
に、これらの既存技術では材質特性の異方性が大きいた
め、溶接前の曲げ加工工程における変形挙動がノーマル
法とリバース法とで異なりノーマル法とリバース法の胴
材が混在すると、製缶設備が故障停止するという問題も
あった。However, this DR steel sheet has a drawback in that the workability deterioration of the steel sheet and the softening of the heat-affected zone of the weld due to the secondary cold rolling strain are remarkable and the flange crack often occurs in the flanging after welding. . As a method for solving this problem, JP-A-58-164752 and JP-A-5-16572 are available.
A method described in 9-89718 is proposed. However, in these existing technologies, since the reduction ratio of the secondary cold rolling is as large as about 15% or more, the anisotropy of the material properties of the steel sheet including the flange formability is large, and the rolling direction of the steel sheet is Plate cutting that is parallel to the axial direction (hereinafter,
When this stripping method is referred to as the reverse method), flange cracking frequently occurs after welding, so the can-maker must always strip the steel sheet at a right angle to the axial direction of the can body (hereinafter, This method is called a normal method), and there is a problem that it has to be constrained. Furthermore, since these existing technologies have large anisotropy in material properties, the deformation behavior in the bending process before welding differs between the normal method and the reverse method, and if the body materials of the normal method and the reverse method are mixed, the can manufacturing equipment There was also a problem that it would stop due to failure.
【0008】さらに、溶接速度は生産性向上のために、
高速化される趨勢にある。溶接速度を高速化するには、
接合に必要なエネルギーをより短時間で入力しなければ
ならないので、電流および周波数を高める必要がある。
また、リーディング・エッジの咬み込みとトレーリング
・エッジの離脱の繰り返しから来る回転電極の機械的振
動を抑え、回転電極と鋼板を安定して接触させるため
に、回転電極の圧下圧力を高める必要がある。これらの
条件の変化は溶接後のラップ幅の制御を困難にし、リー
ディング・エッジのラップ幅は適正でも、トレーリング
・エッジに近づくにつれてラップ幅が小さくなり、つい
にはラップがはずれて開いてしまう現象が起こりやすく
なるという問題がある。この現象はラップ逃げと称し、
高速溶接を工業化する上での重要な課題である。[0008] Further, the welding speed is to improve productivity,
There is a trend toward faster speeds. To increase the welding speed,
Since the energy required for joining must be input in a shorter time, it is necessary to increase the current and frequency.
In addition, in order to suppress mechanical vibration of the rotating electrode due to repetition of biting of the leading edge and detachment of the trailing edge and to bring the rotating electrode and the steel plate into stable contact, it is necessary to increase the pressing pressure of the rotating electrode. is there. The change in these conditions makes it difficult to control the lap width after welding, and even if the wrap width at the leading edge is proper, the lap width becomes smaller as it approaches the trailing edge, and eventually the lap comes off and opens. Is likely to occur. This phenomenon is called lap escape,
This is an important issue in industrializing high-speed welding.
【0009】[0009]
【発明が解決しようとする課題】本発明は、上記の問題
点を解決し、製缶業者における板取り方向の制約を完全
に取り除き、ノーマル法、リバース法、およびそれらの
混在のいずれの板取りでも製缶可能であると同時に、ラ
ップ逃げが起こりにくく、高速溶接に適した溶接缶胴用
の0.15mm以下の特に薄い板厚で強度特性が高い極
薄鋼板の製造法を提供することを目的とするものであ
る。DISCLOSURE OF THE INVENTION The present invention solves the above problems and completely removes the restriction of the plate making direction in a can manufacturing company, and makes any of the normal method, the reverse method and a mixture thereof. However, it is possible to provide a method for manufacturing an ultra-thin steel sheet that is capable of producing cans, is less likely to cause lap escape, and has a particularly thin plate thickness of 0.15 mm or less and high strength characteristics suitable for high-speed welding. It is intended.
【0010】[0010]
【課題を解決するための手段】本発明者らは、上記の目
的を達成するために実験、研究を行った結果、板取り性
および耐ラップ逃げ性を高めるには、鋼板強度を確保し
かつ圧延直交方向の延性劣化を生じさせないことが重要
であり、これにはC量の調整、熱間圧延に先立つ鋼片加
熱条件、熱延条件、2次冷間圧延圧下率を組み合わせれ
ばよいことを新規に知見した。Means for Solving the Problems As a result of experiments and research for achieving the above-mentioned objects, the present inventors have found that in order to improve the stripping property and the lap escape resistance, it is necessary to secure the steel plate strength and It is important not to cause deterioration of ductility in the direction orthogonal to the rolling, and for this purpose, adjustment of the C content, billet heating conditions prior to hot rolling, hot rolling conditions, and secondary cold rolling reduction should be combined. Was newly discovered.
【0011】本発明はこの知見に基づいて構成されたも
のであり、その要旨は下記のとおりである。 (1)重量%で、 C:0.0060%以下 Si:0.06%以下 Mn:0.05〜0.60% P:0.06%以下 S:0.06%以下 酸可溶Al:0.005〜0.100% N:0.0060%超 を含み、残部が鉄および不可避的不純物からなる鋼片
(スラブ)を、Ar3変態点未満に冷却し、1050℃
以上のスラブ再加熱温度に加熱し、熱間圧延し、Ar3
変態点以上の温度で仕上げ、酸洗し、冷間圧延し、再結
晶焼鈍し、10%以上60%未満の圧下率で2次冷間圧
延を施し、板厚が0.15mm以下、HR30- T 硬さが6
2以上でかつ圧延方向の引張強さを44kgf/mm2
以上としたことを特徴とする高速溶接に適した溶接缶胴
用極薄鋼板の製造法。The present invention is constructed on the basis of this finding, and the summary thereof is as follows. (1) In% by weight, C: 0.0060% or less Si: 0.06% or less Mn: 0.05 to 0.60% P: 0.06% or less S: 0.06% or less Acid-soluble Al: A steel slab (slab) containing 0.005 to 0.100% N: more than 0.0060% and the balance consisting of iron and unavoidable impurities is cooled to below the Ar 3 transformation point, and heated to 1050 ° C.
Heating to the above slab reheating temperature, hot rolling, Ar 3
Finishing at a temperature above the transformation point, pickling, cold rolling, recrystallization annealing, secondary cold rolling at a rolling reduction of 10% or more and less than 60%, plate thickness of 0.15 mm or less, H R30 - T hardness of 6
2 or more and a rolling direction tensile strength of 44 kgf / mm 2
A method for producing an ultra-thin steel sheet for a welding can body suitable for high-speed welding, which is characterized as described above.
【0012】(2)重量%で、 C:0.0060%以下 Si:0.06%以下 Mn:0.05〜0.60% P:0.06%以下 S:0.06%以下 酸可溶Al:0.005〜0.100% N:0.0060%超 を含み、残部が鉄および不可避的不純物からなる鋼片
(スラブ)を、鋳造後Ar 3変態点未満に冷却すること
なく、高温鋼片(スラブ)のまま表面温度900℃以上
で熱間圧延を開始し、Ar3変態点以上の温度で仕上
げ、酸洗し、冷間圧延し、再結晶焼鈍し、10%以上6
0%未満の圧下率で2次冷間圧延を施し、板厚が0.1
5mm以下、HR30-T 硬さが62以上でかつ圧延方向の
引張強さを44kgf/mm2 以上としたことを特徴と
する高速溶接に適した溶接缶胴用極薄鋼板の製造法。(2) C: 0.0060% or less Si: 0.06% or less Mn: 0.05 to 0.60% P: 0.06% or less S: 0.06% or less Acid acceptable Molten Al: 0.005 to 0.100%, N: more than 0.0060%, and the balance being iron and unavoidable impurities
After casting (slab), Ar 3Cooling below the transformation point
Without, high temperature billet (slab) surface temperature 900 ℃ or more
Start hot rolling at3Finish at a temperature above the transformation point
, Pickling, cold rolling, recrystallization annealing, 10% or more 6
Secondary cold rolling is performed at a rolling reduction of less than 0%, and the plate thickness is 0.1.
5 mm or less, HR30-THardness of 62 or more and rolling direction
Tensile strength of 44kgf / mm2It is characterized by the above
A method of manufacturing ultra-thin steel plates for welding can bodies suitable for high-speed welding.
【0013】(3)前記鋼片はさらに、重量%で、 Cr:0.005〜0.100% を含む前項(1)または(2)記載の高速溶接に適した
溶接缶胴用極薄鋼板の製造法。(3) The steel slab further contains Cr: 0.005 to 0.100% by weight, which is suitable for high-speed welding according to the above (1) or (2). Manufacturing method.
【0014】[0014]
【作用】以下、本発明を詳細に説明する。C量は、これ
が0.0060%超になると耐ラップ逃げ性が劣化し、
フランジ加工性がノーマル法、リバース法のいずれの場
合も顕著に劣化するので、その上限を0.0060%と
する。The present invention will be described in detail below. If the C content exceeds 0.0060%, the lap escape resistance deteriorates,
Since the flange formability is significantly deteriorated in both the normal method and the reverse method, the upper limit is set to 0.0060%.
【0015】Si量は、これが0.06%を超えると、
耐ラップ逃げ性が劣化し、めっき密着性が劣化し、フラ
ンジ加工性が劣化し、耐食性が劣化するので、上限を
0.06%とする。Mn量は、これが0.60%を超え
ると、鋼板が過度に硬質化してフランジ加工性および耐
ラップ逃げ性が劣化するとともに、コスト高となるの
で、上限を0.60%に限定する。また、Mn量が0.
05%を下回ると、鋼板が軟質化し、HR30-T 硬さが6
2以上でかつ圧延方向の引張強さが44kgf/mm2
以上なる強度を確保できないので、その下限を0.05
%に限定する。When the Si content exceeds 0.06%,
The lap escape resistance deteriorates, the plating adhesion deteriorates, the flange formability deteriorates, and the corrosion resistance deteriorates, so the upper limit is made 0.06%. If the amount of Mn exceeds 0.60%, the steel sheet is excessively hardened to deteriorate the flange formability and the lap escape resistance, and the cost increases, so the upper limit is set to 0.60%. In addition, the Mn content is 0.
If it is less than 05%, the steel sheet becomes soft and the H R30-T hardness is 6
2 or more and the tensile strength in the rolling direction is 44 kgf / mm 2
Since the strength above cannot be secured, the lower limit is set to 0.05
Limited to%.
【0016】P量は、これが0.06%を超えると、鋼
板が過度に硬質化してフランジ加工性および耐ラップ逃
げ性が劣化するとともに、耐食性が劣化するので、上限
を0.06%とする。S量は、これが0.06%を超え
ると、熱間脆性を昂進させるので、上限を0.06%と
する。When the amount of P exceeds 0.06%, the steel sheet is excessively hardened to deteriorate the flange formability and the lap escape resistance, and the corrosion resistance is deteriorated. Therefore, the upper limit is made 0.06%. . If the amount of S exceeds 0.06%, hot brittleness is promoted, so the upper limit is made 0.06%.
【0017】酸可溶Alは、これが0.100%を超え
ると、固溶Alが鋼板を硬質化してフランジ加工性およ
び耐ラップ逃げ性を劣化させるとともに、コスト高とな
るので、その上限を0.100%とする。また、酸可溶
Alが0.005%を下回ると、理由は明らかでないが
耐ラップ逃げ性が劣化すると同時に、脱酸が不十分とな
り、介在物の多い鋼板となってフランジ加工性が劣化す
るので、その下限を0.005%とする。When the content of acid-soluble Al exceeds 0.100%, the solid-solution Al hardens the steel sheet to deteriorate the flange formability and the lap escape resistance, and the cost becomes high. Therefore, the upper limit is set to 0. 100%. Further, when the acid-soluble Al content is less than 0.005%, the lap escape resistance deteriorates at the same time as the reason is not clear, but at the same time, deoxidation becomes insufficient and a steel sheet with a large amount of inclusions deteriorates the flange formability. Therefore, the lower limit is made 0.005%.
【0018】N量は、これが0.0060%以下になる
と、耐ラップ逃げ性が顕著に劣化するばかりでなく、鋼
板が軟質化しHR30-T 硬さが62以上でかつ圧延方向の
引張強さが44kgf/mm2 以上なる強度を確保でき
ず、所定の強度を確保するために2次冷間圧延率を高め
ざるを得なくなるところからリバース法でのフランジ加
工性が劣化し、従って板取り性が劣化するので、0.0
060%超に限定する。When the N content is 0.0060% or less, not only the lap escape resistance is significantly deteriorated, but also the steel sheet is softened and the H R30-T hardness is 62 or more and the tensile strength in the rolling direction is high. Of 44 kgf / mm 2 or more cannot be ensured, and the secondary cold rolling rate must be increased in order to ensure a predetermined strength, so the flange formability by the reverse method deteriorates, and thus the stripping property is reduced. Deteriorates, so 0.0
Limited to more than 060%.
【0019】Cr量は、これが0.005%を下回る
と、非酸化雰囲気中の焼鈍時に鋼板表面に黒鉛が析出す
るいわゆるカーボン汚れを生じやすく、商品価値を著し
く減じるので、0.005%以上添加することが望まし
い。また、これが0.100%を上回ると、添加合金の
コスト高となるため、上限を0.100%とする。これ
らの成分を含有し、残部が鉄および不可避的不純物から
なる鋼を造塊または連続鋳造で鋼片(スラブ)とし、熱
間圧延に供する。If the Cr content is less than 0.005%, so-called carbon stains in which graphite precipitates on the surface of the steel sheet during annealing in a non-oxidizing atmosphere are prone to occur, which significantly reduces the commercial value, so 0.005% or more is added. It is desirable to do. Further, if it exceeds 0.100%, the cost of the additive alloy increases, so the upper limit is made 0.100%. Steel containing these components and the balance consisting of iron and unavoidable impurities is made into a billet (slab) by ingot casting or continuous casting, and subjected to hot rolling.
【0020】熱間圧延前の鋼片(スラブ)の熱履歴は、
一旦Ar3変態点未満に冷却された後再加熱される通常
の工程、およびAr3変態点未満に冷却されることなく
高温鋼片(スラブ)のまま熱間圧延に供されるいわゆる
直送圧延工程のいずれもとりうる。まず、一旦Ar3変
態点未満に冷却された後再加熱される通常の工程の場合
は、スラブ再加熱温度が1050℃を下回ると、冷却時
に析出したAlNが溶解せず、固溶Nの固溶強化による
製品強度の確保ができず、その後の2次冷間圧延で強度
を確保しようとすると板取り性が劣化するので、スラブ
再加熱温度の下限を1050℃に限定する。また理由は
明らかでないが、スラブ再加熱温度が1050℃を下回
ると、耐ラップ逃げ性も劣化する。一方、Ar3変態点
未満に冷却されることなく高温鋼片(スラブ)のまま熱
間圧延に供されるいわゆる直送圧延工程の場合は、鋼片
(スラブ)表面温度が900℃を下回ると、固溶NがA
lNとして析出し、固溶Nの固溶強化による製品強度の
確保ができず、この場合にも板取り性および耐ラップ逃
げ性が劣化するので、表面温度の下限を900℃に限定
する。The heat history of the steel slab (slab) before hot rolling is
A normal process in which the material is once cooled below the Ar 3 transformation point and then reheated, and a so-called direct rolling process in which a high temperature steel slab (slab) is subjected to hot rolling without being cooled below the Ar 3 transformation point. Either of these can be taken. First, in the case of a normal process in which the material is once cooled to below the Ar 3 transformation point and then reheated, when the slab reheating temperature is lower than 1050 ° C., AlN precipitated during cooling does not dissolve and solid solution N The product strength cannot be ensured by solution strengthening, and if the strength is to be secured in the subsequent secondary cold rolling, the stripping property deteriorates, so the lower limit of the slab reheating temperature is limited to 1050 ° C. Although the reason is not clear, when the slab reheating temperature is lower than 1050 ° C, the lap escape resistance also deteriorates. On the other hand, in the case of a so-called direct rolling process in which the high temperature steel slab (slab) is subjected to hot rolling without being cooled to below the Ar 3 transformation point, when the steel slab (slab) surface temperature is lower than 900 ° C, Solid solution N is A
Since it precipitates as 1N and the strength of the product cannot be secured by solid solution strengthening of solid solution N, and in this case also, the plate cutting property and the lap escape resistance deteriorate, so the lower limit of the surface temperature is limited to 900 ° C.
【0021】熱間圧延仕上温度は、これがAr3変態点
を下回ると、混粒組織となり、均一な材質が得られない
ので、その下限をAr3変態点に限定する。熱間圧延捲
取温度は限定しないが、これが680℃を超えると、A
lNが析出して固溶Nが減少し鋼板が軟質化しHR30-T
硬さが62以上でかつ圧延方向の引張強さが44kgf
/mm2 以上なる強度を確保しにくい場合があり、ま
た、耐ラップ逃げ性が劣化し、また、熱延板の炭化物が
塊状化して耐食性を劣化させる傾向もあるため、その上
限を680℃とすることが望ましい。When the hot rolling finishing temperature is below the Ar 3 transformation point, a mixed grain structure is formed and a uniform material cannot be obtained, so the lower limit is set to the Ar 3 transformation point. The hot rolling coiling temperature is not limited, but if it exceeds 680 ° C, A
1N precipitates, solute N decreases, and the steel sheet softens and becomes H R30-T
Hardness is 62 or more and tensile strength in rolling direction is 44kgf
/ Mm 2 or more, it may be difficult to secure the strength, the lap escape resistance may deteriorate, and the carbide of the hot-rolled sheet tends to agglomerate to deteriorate the corrosion resistance. Therefore, the upper limit is 680 ° C. It is desirable to do.
【0022】熱間圧延の終了した鋼帯は、常法により、
酸洗し、冷間圧延し、再結晶焼鈍を施される。再結晶焼
鈍の後、2次冷間圧延を行う。2次冷間圧延の圧下率
は、これが10%を下回ると、HR30-T 硬さが62以上
でかつ圧延方向の引張強さが44kgf/mm2 以上な
る強度を確保できないので、その下限を10%以上に限
定する。鋼板板厚が0.15mm以下でも特に優れた缶
強度を確保するためには2次冷間圧延率は15%以上と
することが好ましい。また、その圧下率が60%以上に
なると耐ラップ逃げ性が顕著に劣化するとともに、リバ
ース法におけるフランジ加工性が顕著に劣化し、材質特
性の異方性が大きくなるので、その上限を60%未満に
限定する。The steel strip after hot rolling is
It is pickled, cold rolled and recrystallized annealed. After recrystallization annealing, secondary cold rolling is performed. If the rolling reduction ratio of the secondary cold rolling is less than 10%, it is impossible to secure the strength such that the HR30 -T hardness is 62 or more and the tensile strength in the rolling direction is 44 kgf / mm 2 or more. Limited to 10% or more. Even if the steel plate has a thickness of 0.15 mm or less, the secondary cold rolling rate is preferably 15% or more in order to secure particularly excellent can strength. Further, when the rolling reduction is 60% or more, the lap escape resistance is significantly deteriorated, the flange formability in the reverse method is significantly deteriorated, and the anisotropy of the material properties is increased. Therefore, the upper limit is 60%. Limited to less than.
【0023】2次冷間圧延後の鋼板板厚は0.15mm
以下とするが、これは缶素材を特に薄手化し缶の軽量化
さらに省資源化をはかるためである。好ましい範囲は
0.13mm以下である。また、鋼板のHR30-T 硬さを
62以上でかつ圧延方向の引張強さを44kgf/mm
2 以上と規定するのは、板厚の薄手化を補って所定の缶
強度を確保するためである。The thickness of the steel plate after the secondary cold rolling is 0.15 mm
This is because the can material is made particularly thin to reduce the weight of the can and save resources. The preferred range is 0.13 mm or less. Also, the H R30-T hardness of the steel sheet is 62 or more and the tensile strength in the rolling direction is 44 kgf / mm.
The reason for defining 2 or more is to compensate for the thinning of the plate thickness and to secure a predetermined can strength.
【0024】本発明の製造法において鋼板に施される表
面処理は、その方法を問わない。すなわち、すずめっ
き、ニッケルめっき、あるいは特殊な下地処理後に極薄
目付けのすずめっきを行う方法など、溶接缶用鋼板に用
いられるいかなるめっきであっても、本発明の作用効果
は発揮される。The surface treatment applied to the steel sheet in the manufacturing method of the present invention does not matter. That is, the effects of the present invention can be exerted by any plating used for steel plates for welding cans, such as tin plating, nickel plating, or a method of performing ultra-thin weight tin plating after special undercoating.
【0025】[0025]
【実施例】まず、熱間圧延前の鋼片(スラブ)の熱履歴
が一旦Ar3変態点未満に冷却された後再加熱される通
常の工程をとる場合の実施例を示す。表1記載の成分を
有する鋼を転炉で溶製し、スラブを室温まで冷却した
後、同表記載のスラブ再加熱温度まで再加熱し、それぞ
れ同表記載の熱延条件で板厚3.0mmまで熱間圧延
し、酸洗し、冷間圧延し、連続焼鈍し、同表記載の2次
冷間圧延率で板厚0.13mmまで2次冷間圧延し、N
iめっきクロメート処理を行った。EXAMPLE First, an example will be shown in which a normal process in which the heat history of a steel slab (slab) before hot rolling is once cooled below the Ar 3 transformation point and then reheated is taken. Steels having the components shown in Table 1 were melted in a converter, the slabs were cooled to room temperature, and then reheated to the slab reheating temperature shown in the same table. Hot rolling to 0 mm, pickling, cold rolling, continuous annealing, secondary cold rolling to a plate thickness of 0.13 mm at the secondary cold rolling rate shown in the table, N
An i-plated chromate treatment was performed.
【0026】このようにして得られたNiめっきクロメ
ート処理鋼板の硬さ、引張強さ、ラップ逃げ量および伸
びフランジ加工率を表2に示す。ここで、ラップ逃げ量
とは、本発明者らの実験室の高速ワイヤーシーム溶接機
を用いて最大圧力を加えて溶接した時のリーディング・
エッジとトレーリング・エッジのラップ幅の差を言い、
これまでの実験の結果、このラップ逃げ量が0.2mm
以下であれば、需要家において毎分30メートル以上の
線速度の高速溶接にも耐えることがわかっている。そこ
でラップ逃げ量が0.2mm以下のものを合格(○で表
示)、0.2mm超のものを不合格(×で表示)と判定
した。また、伸びフランジ加工率とは、本発明者らの実
験室のフランジ成形機にて溶接缶のフランジ加工のシミ
ュレーションを行った場合の破断発生までの加工率を言
い、本発明者らの実験室における測定法の場合、9.0
%以上が需要家においても合格と評価されることがわか
っている。そこでこれが9.0%以上のものを合格(○
で表示)、9.0%未満のものを不合格(×で表示)と
判定した。Table 2 shows the hardness, the tensile strength, the lap clearance and the stretch-flange processing rate of the Ni-plated chromate-treated steel sheet thus obtained. Here, the lap relief amount is a reading when welding is performed by applying maximum pressure using a high speed wire seam welding machine in the laboratory of the present inventors.
The difference in the wrap width between the edge and the trailing edge,
As a result of experiments so far, this lap relief amount is 0.2 mm
It has been found that, if the following is satisfied, even a consumer can withstand high-speed welding at a linear velocity of 30 meters per minute or more. Therefore, those with a lap relief amount of 0.2 mm or less were judged to be acceptable (indicated by ◯), and those with an amount of over 0.2 mm were judged to be unacceptable (indicated by x). Further, the stretch-flange processing rate refers to a processing rate up to occurrence of fracture when a simulation of flange processing of a welding can is performed by a flange forming machine of the inventors of the present invention, and the laboratory of the present inventors of the present invention In the case of the measuring method in
It is known that even more than 100% of customers are evaluated as passing. Therefore, if this is 9.0% or more, it passes (○
Indicated by () and less than 9.0% were judged as rejected (indicated by x).
【0027】これらの表において、本発明の範囲からは
ずれた数値は下線をつけて示してある。表1および表2
からわかるように、本発明鋼はHR30-T硬さが62以上
でかつ引張強さが44kgf/mm2 以上の高い強度を
持つため、板厚の薄手化に伴う缶強度の低下を十分補償
することができる。しかも、伸びフランジ加工率は、ノ
ーマル法、リバース法のいずれの場合も高く、ノーマル
法、リバース法のいずれの板取りにも対応できるという
大きな特徴を有している。また、ラップ逃げ量が小さ
く、高速溶接にも適する。In these tables, numerical values outside the scope of the present invention are underlined. Table 1 and Table 2
As can be seen from the above, the steel of the present invention has a high strength of H R30-T hardness of 62 or more and a tensile strength of 44 kgf / mm 2 or more, so that the reduction of the can strength due to the thinning of the plate thickness is sufficiently compensated. can do. In addition, the stretch-flange processing rate is high in both the normal method and the reverse method, and it has a great feature that it can be used for both the normal method and the reverse method. Also, the amount of lap escape is small, making it suitable for high-speed welding.
【0028】次に、熱間圧延前の鋼片(スラブ)の熱履
歴がAr3変態点未満に冷却されることなく高温鋼片
(スラブ)のまま熱間圧延に供されるいわゆる直送圧延
工程をとる場合の実施例を示す。表3記載の成分を有す
る鋼を転炉で溶製し、鋼片(スラブ)をAr3変態点未
満に冷却することなく同表記載の鋼片(スラブ)表面温
度のまま熱間圧延を開始し、それぞれ同表記載の熱延条
件で板厚3.0mmまで熱間圧延し、酸洗し、冷間圧延
し、連続焼鈍し、同表記載の2次冷間圧延率で板厚0.
13mmまで2次冷間圧延し、Niめっきクロメート処
理を行った。Next, a so-called direct rolling process in which the hot history of the steel slab (slab) before hot rolling is used for hot rolling as it is without being cooled to below the Ar 3 transformation point An example in the case of taking Steel having the components shown in Table 3 is melted in a converter, and hot rolling is started without cooling the steel slab (slab) to below the Ar 3 transformation point at the steel slab (slab) surface temperature shown in the same table. Then, each was hot-rolled under the hot rolling conditions shown in the table to a plate thickness of 3.0 mm, pickled, cold-rolled, and continuously annealed, and the plate thickness of 0.
Secondary cold rolling was performed to 13 mm, and Ni plating chromate treatment was performed.
【0029】このようにして得られたNiめっきクロメ
ート処理鋼板の硬さ、引張強さ、ラップ逃げ量および伸
びフランジ加工率を表4に示す。これらの表において、
本発明の範囲からはずれた数値は下線をつけて示してあ
る。表3および表4からわかるように、本発明鋼はH
R30-T硬さが62以上でかつ引張強さが44kgf/m
m2 以上の高い強度を持つため、板厚の薄手化に伴う缶
強度の低下を十分補償することができる。しかも、伸び
フランジ加工率は、ノーマル法、リバース法のいずれの
場合も高く、ノーマル法、リバース法のいずれの板取り
にも対応できるという大きな特徴を有している。また、
ラップ逃げ量が小さく、高速溶接にも適する。Table 4 shows the hardness, the tensile strength, the lap relief amount and the stretch-flange processing rate of the Ni-plated chromate-treated steel sheet thus obtained. In these tables,
Numerical values outside the scope of the present invention are underlined. As can be seen from Tables 3 and 4, the steels of the present invention have H
R30-T hardness is 62 or more and tensile strength is 44kgf / m
Since it has a high strength of m 2 or more, it is possible to sufficiently compensate for the decrease in can strength that accompanies a thinner plate thickness. In addition, the stretch-flange processing rate is high in both the normal method and the reverse method, and it has a great feature that it can be used for both the normal method and the reverse method. Also,
Small amount of lap relief, suitable for high speed welding.
【0030】[0030]
【表1】 [Table 1]
【0031】[0031]
【表2】 [Table 2]
【0032】[0032]
【表3】 [Table 3]
【0033】[0033]
【表4】 [Table 4]
【0034】[0034]
【発明の効果】本発明は、HR30-T硬さが62以上でか
つ圧延方向の引張強さが44kgf/mm2 以上なる板
厚0.15mm以下の極薄溶接缶胴用の高強度極薄鋼板
を製造するにあたり、製缶業者における板取り方向の制
約を完全に取り除き、ノーマル法、リバース法、および
それらの混在のいずれの板取りでも製缶可能で、かつ高
速溶接にも適する鋼板の製造法を提供するものであり、
その工業的価値はきわめて大きい。EFFECT OF THE INVENTION The present invention provides a high strength electrode for an ultra-thin welded can body having an H R30-T hardness of 62 or more and a tensile strength in the rolling direction of 44 kgf / mm 2 or more and a plate thickness of 0.15 mm or less. When manufacturing a thin steel sheet, the restrictions on the plate-making direction of a can manufacturer are completely removed, and it is possible to make a plate by any of the normal method, the reverse method, and a mixture of these methods. Provides a manufacturing method,
Its industrial value is extremely high.
フロントページの続き (72)発明者 池田 昌男 福岡県北九州市戸畑区飛幡町1番1号 新 日本製鐵株式会社八幡製鐵所内 (72)発明者 河野 彪 福岡県北九州市戸畑区飛幡町1番1号 新 日本製鐵株式会社八幡製鐵所内Front page continued (72) Inventor Masao Ikeda 1-1 Tobata-cho, Tobata-ku, Kitakyushu, Fukuoka Prefecture Inside the Yawata Works, Shin Nippon Steel Co., Ltd. (72) Inoue Kono, No. 1 Tobita-cho, Tobata-ku, Kitakyushu, Fukuoka No. 1 inside Nippon Steel Co., Ltd. Yawata Works
Claims (3)
(スラブ)を、Ar3変態点未満に冷却し、1050℃
以上のスラブ再加熱温度に加熱し、熱間圧延し、Ar3
変態点以上の温度で仕上げ、酸洗し、冷間圧延し、再結
晶焼鈍し、10%以上60%未満の圧下率で2次冷間圧
延を施し、板厚が0.15mm以下、HR30- T 硬さが6
2以上でかつ圧延方向の引張強さを44kgf/mm2
以上としたことを特徴とする高速溶接に適した溶接缶胴
用極薄鋼板の製造法。1. C .: 0.0060% or less Si: 0.06% or less Mn: 0.05 to 0.60% P: 0.06% or less S: 0.06% or less Acid soluble A steel slab (slab) containing Al: 0.005 to 0.100% N: more than 0.0060% and the balance iron and unavoidable impurities is cooled to below the Ar 3 transformation point, and heated to 1050 ° C.
Heating to the above slab reheating temperature, hot rolling, Ar 3
Finishing at a temperature above the transformation point, pickling, cold rolling, recrystallization annealing, secondary cold rolling at a rolling reduction of 10% or more and less than 60%, plate thickness of 0.15 mm or less, H R30 - T hardness of 6
2 or more and a rolling direction tensile strength of 44 kgf / mm 2
A method for producing an ultra-thin steel sheet for a welding can body suitable for high-speed welding, which is characterized as described above.
(スラブ)を、鋳造後Ar 3変態点未満に冷却すること
なく、高温鋼片(スラブ)のまま表面温度900℃以上
で熱間圧延を開始し、Ar3変態点以上の温度で仕上
げ、酸洗し、冷間圧延し、再結晶焼鈍し、10%以上6
0%未満の圧下率で2次冷間圧延を施し、板厚が0.1
5mm以下、HR30-T 硬さが62以上でかつ圧延方向の
引張強さを44kgf/mm2 以上としたことを特徴と
する高速溶接に適した溶接缶胴用極薄鋼板の製造法。2. C .: 0.0060% or less Si: 0.06% or less Mn: 0.05 to 0.60% P: 0.06% or less S: 0.06% or less Acid soluble A slab containing Al: 0.005 to 0.100% N: more than 0.0060% and the balance iron and unavoidable impurities.
After casting (slab), Ar 3Cooling below the transformation point
Without, high temperature billet (slab) surface temperature 900 ℃ or more
Start hot rolling at3Finish at a temperature above the transformation point
, Pickling, cold rolling, recrystallization annealing, 10% or more 6
Secondary cold rolling is performed at a rolling reduction of less than 0%, and the plate thickness is 0.1.
5 mm or less, HR30-THardness of 62 or more and rolling direction
Tensile strength of 44kgf / mm2It is characterized by the above
A method of manufacturing ultra-thin steel plates for welding can bodies suitable for high-speed welding.
胴用極薄鋼板の製造法。3. The method for producing an ultra-thin steel sheet for a can body suitable for high speed welding according to claim 1 or 2, wherein the steel billet further contains Cr: 0.005 to 0.100% by weight.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP25457093A JPH07109527A (en) | 1993-10-12 | 1993-10-12 | Production of extra thin steel sheet for welded can body, suitable for high speed welding |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP25457093A JPH07109527A (en) | 1993-10-12 | 1993-10-12 | Production of extra thin steel sheet for welded can body, suitable for high speed welding |
Publications (1)
Publication Number | Publication Date |
---|---|
JPH07109527A true JPH07109527A (en) | 1995-04-25 |
Family
ID=17266885
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP25457093A Withdrawn JPH07109527A (en) | 1993-10-12 | 1993-10-12 | Production of extra thin steel sheet for welded can body, suitable for high speed welding |
Country Status (1)
Country | Link |
---|---|
JP (1) | JPH07109527A (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR100515488B1 (en) * | 1995-02-24 | 2005-11-21 | 솔락 | Method for producing steel sheet or strip for canning, and steel sheet or strip manufactured by the above method |
-
1993
- 1993-10-12 JP JP25457093A patent/JPH07109527A/en not_active Withdrawn
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR100515488B1 (en) * | 1995-02-24 | 2005-11-21 | 솔락 | Method for producing steel sheet or strip for canning, and steel sheet or strip manufactured by the above method |
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