JPH1030152A - Steel sheet suitable for use in thin deep-drawn can, and its production - Google Patents
Steel sheet suitable for use in thin deep-drawn can, and its productionInfo
- Publication number
- JPH1030152A JPH1030152A JP10077097A JP10077097A JPH1030152A JP H1030152 A JPH1030152 A JP H1030152A JP 10077097 A JP10077097 A JP 10077097A JP 10077097 A JP10077097 A JP 10077097A JP H1030152 A JPH1030152 A JP H1030152A
- Authority
- JP
- Japan
- Prior art keywords
- steel sheet
- rolling
- overaging treatment
- elongation
- hot
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
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- Heat Treatment Of Sheet Steel (AREA)
Abstract
Description
【0001】[0001]
【発明の属する技術分野】本発明は食品缶、飲料缶等の
容器材料に関し、特に深絞り加工性に優れ、肌荒れ性が
良く、耐食性の優れた薄肉化深絞り缶用途に適した鋼板
およびそ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 container material for food cans, beverage cans and the like, and more particularly to a steel sheet suitable for use in a thin-walled deep-drawing can which is excellent in deep-drawing workability, has good surface roughness, and has excellent corrosion resistance. It concerns the manufacturing method.
【0002】[0002]
【従来の技術】従来、側面無継目(サイドシームレス)
缶の成形法として、表面処理鋼板を成形した後の缶の内
外に有機塗料を施す方法と、成形前の金属板にあらかじ
め樹脂フィルムを被覆し、樹脂フィルムを一種の成形潤
滑剤とし、缶側壁となる部分の金属板を薄肉化する、い
わゆる薄肉化絞り缶成形法とがある。後者の例として、
本発明者らは先に、金属板の平均結晶粒径及び平均表面
粗さを特定することにより、製缶後の耐肌荒れ性および
耐食性に優れた薄肉化絞り缶用の金属板を提案した(特
開平4−314535号参照)。2. Description of the Related Art Conventionally, a side seam is seamless.
As a method of forming a can, a method of applying an organic paint to the inside and outside of the can after forming a surface-treated steel sheet, a method of coating a metal sheet before forming with a resin film in advance, using the resin film as a kind of forming lubricant, There is a so-called thinned draw can molding method for reducing the thickness of a metal plate in a portion to be formed. As an example of the latter,
The present inventors have previously proposed a metal plate for a thinned drawn can having excellent surface roughness and corrosion resistance after can making by specifying the average crystal grain size and the average surface roughness of the metal plate ( JP-A-4-314535).
【0003】[0003]
【発明が解決しようとする課題】しかしながら、従来の
あらかじめ樹脂フィルムを被覆した金属板を用いて薄肉
化絞り缶を成形すると、完成後の缶側壁が極めて肌荒れ
しやすいという問題がある。すなわち、ダイスとポンチ
のクリアランスが缶側壁の厚みより大きく、加工時にお
いて缶側壁がポンチとダイスに拘束されず、いわゆる自
由表面となっているので、DI(Draw and I
roning)成形法と比べ缶側壁が肌荒れしやすいと
いう問題がある。この肌荒れ状態が生ずると、原板とフ
ィルムの密着力が減少し、フィルム剥離の一因ともな
る。また肌荒れは、輸送中の缶同士の接触などの外部か
らの衝撃が引き金になり、フィルム面に微細なクラック
を生じさせ、ひいては耐食性の劣化を招くという問題も
ある。通常、薄肉化深絞り缶は被覆金属板を円板状に打
ち抜き、これを二段階の絞り加工によって成形される。
この二段目の絞り加工(再絞り加工)時においては、フ
ランジ部に高いしわ押え力を加え、缶側壁の絞り−張り
出し加工を行なうことにより、缶側壁の厚みを減少させ
ている。上記の加工法において、再絞り加工は極めて過
酷な成形法であるため、連続成形時に破胴が起こりやす
いという問題があった。このような破胴が起こると高速
製缶加工の生産性を損なうため、破胴が起こりにくく、
しかも加工性に優れた薄肉化深絞り缶用途に適した鋼板
を開発することは急務であった。本発明は上記問題点を
解決することを目的とし、肌荒れ性、耐食性が優れ、連
続高速製缶加工時において、破胴が起きず、しかも加工
性に優れた薄肉化深絞り缶用途に適した鋼板およびその
製造法を提供することを目的とする。However, when a thinned drawn can is formed by using a conventional metal plate previously coated with a resin film, there is a problem that the completed can side wall is extremely rough. That is, since the clearance between the die and the punch is larger than the thickness of the can side wall, and the can side wall is not restricted by the punch and the die during processing, and has a so-called free surface, DI (Draw and I)
There is a problem that the side wall of the can is easily roughened as compared with the molding method. When this rough surface state occurs, the adhesion between the original plate and the film decreases, which also contributes to film peeling. In addition, there is also a problem that the roughened surface is triggered by an external impact such as contact between cans during transportation, which causes fine cracks on the film surface, and eventually causes deterioration of corrosion resistance. Normally, a thin-walled deep-drawing can is formed by punching a coated metal plate into a disk shape and performing a two-stage drawing process.
In the second-stage drawing (redrawing), the thickness of the can side wall is reduced by applying a high wrinkle holding force to the flange portion and performing the drawing-extending process of the can side wall. In the above-mentioned processing method, redrawing is an extremely severe forming method, so that there is a problem that a broken body is likely to occur during continuous forming. If such a fracture occurs, the productivity of high-speed can manufacturing is impaired.
In addition, there was an urgent need to develop a steel sheet that is excellent in workability and suitable for thinning deep drawing cans. The present invention aims to solve the above-mentioned problems, and is suitable for use in thin-walled deep-drawing cans having excellent surface roughness, excellent corrosion resistance, no breakage during continuous high-speed can-making, and excellent workability. An object of the present invention is to provide a steel sheet and a method for manufacturing the same.
【0004】[0004]
【課題を解決するための手段】本発明の薄肉化深絞り缶
用途に適した鋼板は、C:0.01〜0.15%、Si
≦0.05%、Mn≦0.9%、P≦0.04%、S≦
0.04%、Al:0.015〜0.10%、N:0.
0020〜0.015%、残部Feおよび不可避的不純
物からなる熱延鋼板を、冷間圧延、過時効処理を含むヒ
ートサイクルでの焼鈍、伸び率0.5〜2.0%での調
質圧延、を順次行い、調質圧延後の鋼板の平均結晶粒径
が6.0μm以下である薄肉化深絞り用途に適した鋼板
である。さらに、C:0.01〜0.15%、Si≦
0.05%、Mn≦0.9%、P≦0.04%、S≦
0.04%、Al:0.015〜0.10%、N:0.
0020〜0.015%、Nb:0.001〜0.02
0%、残部Feおよび不可避的不純物からなる熱延鋼板
を、冷間圧延、過時効処理を含むヒートサイクルでの焼
鈍、伸び率0.5〜2.0%での調質圧延、を順次行
い、調質圧延後の鋼板の平均結晶粒径が6.0μm以下
であることも望ましい。つぎに、本発明の薄肉化深絞り
缶用途に適した鋼板の製造法は、C:0.01〜0.1
5%、Si≦0.05%、Mn≦0.9%、P≦0.0
4%、S≦0.04%、Al:0.015〜0.10
%、N:0.0020〜0.015%、残部Feおよび
不可避的不純物からなる熱延鋼板を、冷間圧延、過時効
処理を含むヒートサイクルでの焼鈍、伸び率0.5〜
2.0%での調質圧延、を順次行う薄肉化深絞り用途に
適した鋼板の製造法であり、また、C:0.01〜0.
15%、Si≦0.05%、Mn≦0.9%、P≦0.
04%、S≦0.04%、Al:0.015〜0.10
%、N:0.0020〜0.015%、Nb:0.00
1〜0.020%、残部Feおよび不可避的不純物から
なる熱延鋼板を、冷間圧延、過時効処理を含むヒートサ
イクルでの焼鈍、伸び率0.5〜2.0%での調質圧
延、を順次行うことも望ましい。Means for Solving the Problems The steel sheet suitable for use in the thinned deep-drawing can of the present invention is as follows: C: 0.01-0.15%, Si
≦ 0.05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦
0.04%, Al: 0.015 to 0.10%, N: 0.
A hot-rolled steel sheet comprising 0020 to 0.015%, the balance being Fe and unavoidable impurities, is subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%. , And the average grain size of the steel sheet after temper rolling is 6.0 μm or less, which is a steel sheet suitable for thinning and deep drawing. Further, C: 0.01 to 0.15%, Si ≦
0.05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦
0.04%, Al: 0.015 to 0.10%, N: 0.
0020 to 0.015%, Nb: 0.001 to 0.02
A hot-rolled steel sheet comprising 0%, the balance of Fe and unavoidable impurities is sequentially subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%. It is also desirable that the average grain size of the steel sheet after temper rolling is 6.0 μm or less. Next, the method for producing a steel sheet suitable for use in a thinned deep-drawing can according to the present invention is as follows: C: 0.01 to 0.1
5%, Si ≦ 0.05%, Mn ≦ 0.9%, P ≦ 0.0
4%, S ≦ 0.04%, Al: 0.015 to 0.10
%, N: 0.0020 to 0.015%, a hot-rolled steel sheet comprising the balance of Fe and unavoidable impurities is annealed in a heat cycle including cold rolling and overaging, and has an elongation of 0.5 to 0.5%.
This is a method for producing a steel sheet suitable for deep drawing, in which temper rolling at 2.0% is sequentially performed, and C: 0.01 to 0.1.
15%, Si ≦ 0.05%, Mn ≦ 0.9%, P ≦ 0.
04%, S ≦ 0.04%, Al: 0.015 to 0.10
%, N: 0.0020 to 0.015%, Nb: 0.00
A hot-rolled steel sheet comprising 1 to 0.020%, balance Fe and unavoidable impurities, is subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%. , Are preferably performed sequentially.
【0005】[0005]
【発明の実施の形態】本発明の鋼板に、ポリエステル等
の樹脂フィルムを被覆し、円板状に打ち抜き、これを二
段階絞りの連続高速製缶加工を行っても、破胴が起き
ず、しかも加工性に優れた薄肉化深絞り缶を成形でき
る。特に、近年における著しく薄肉化され、また、その
分高強度化された缶用途の鋼板においても、二段階の過
酷な深絞りの際の破胴を生じないための加工性と強度と
を兼ね備え、かつ成形品として肌荒れや耐食性の条件を
満たすことができる。即ち、薄肉化深絞り加工において
は極薄鋼板を素材として、再絞り工程で強いバックテン
ションとポンチ力の負荷のもとで曲率半径の小さいダイ
スコーナーで強度の引張曲げ加工を受けて薄肉化される
ため、これらの薄肉化深絞りの要求に応える高度な加工
性と共にその際破胴発生に至らないための強度が必要で
あり、このため缶強度と加工性の兼ね合いが重要であ
る。本発明においては、冷延後の過時効処理を含むヒー
トサイクル後に、伸び率が0.5〜2.0%になるよう
な調質圧延を組合せることにより、冷延後の過時効処理
による固溶C、Nの低減が図られ、伸び特性が向上して
加工性が向上するという作用と過時効後の調質圧延によ
る板強度の向上とが相俟つて、缶用極薄鋼板において十
分な加工性と破胴を生じない強度とを付与することがで
きる。また、Nbの添加は一般に結晶粒微細化及び固溶
C、Nの低減に寄与することが知られているところであ
るが、冷延後の過時効処理を含む本発明のヒートサイク
ルと組合わされることにより、過時効処理により固溶
C、Nの低減が図られ、伸び特性を含む加工性の向上が
図られることと相俟つて、過時効処理の際の固溶C、N
の低減作用が著しく増進されるのであって、その結晶粒
の粗大化防止効果と相俟つて、肌荒れ防止と共に薄肉化
深絞り加工における破胴防止効果を達成することができ
る。そして、これらの作用・効果は、その特定の成分組
成による性質に基づいて発揮されるのであって、特にC
量の規制とNbの微量の含有がこれらの処理工程と相俟
つて、肌荒れ性の向上に寄与する結晶粒の細粒化が達成
できる。BEST MODE FOR CARRYING OUT THE INVENTION The steel sheet of the present invention is coated with a resin film of polyester or the like, punched into a disc shape, and subjected to continuous high-speed can-making with two-stage drawing, without causing a broken body. Moreover, it is possible to form a thin-walled deep drawn can having excellent workability. In particular, in recent years, the thickness of the steel sheet has been significantly reduced, and also in the steel sheet for cans, which has been increased accordingly, having both workability and strength to prevent the occurrence of a broken body at the time of two-stage severe deep drawing, In addition, it can satisfy the conditions of rough surface and corrosion resistance as a molded product. In other words, in deep drawing, ultra-thin steel sheet is used as a material, and in the redrawing process, it is subjected to strong tensile bending at the die corner with a small radius of curvature under the load of strong back tension and punch force, and the thickness is reduced. Therefore, it is necessary to have high workability to meet the demand for the thinning and deep drawing as well as strength to prevent the occurrence of a broken body at that time, and therefore, a balance between the strength of the can and the workability is important. In the present invention, after the heat cycle including the overaging treatment after the cold rolling, the temper rolling so that the elongation becomes 0.5 to 2.0% is combined, so that the overaging treatment after the cold rolling is performed. The effect of reducing solid solution C and N, improving elongation characteristics and improving workability, and improving the sheet strength by temper rolling after overageing are combined, and it is sufficient for ultra-thin steel sheets for cans. It can provide excellent workability and strength that does not cause a broken body. It is known that the addition of Nb generally contributes to refinement of crystal grains and reduction of solid solution C and N. However, it is combined with the heat cycle of the present invention including overaging treatment after cold rolling. Thereby, the solid solution C and N can be reduced by the overaging treatment, and the workability including the elongation property can be improved.
Is significantly enhanced, and together with the effect of preventing the crystal grains from being coarsened, it is possible to prevent the surface from being roughened and to achieve the effect of preventing the body from being broken in the deep drawing work for thinning the wall. These actions and effects are exhibited based on the properties of the specific component composition.
The regulation of the amount and the inclusion of a small amount of Nb in combination with these treatment steps can achieve the refinement of crystal grains which contributes to the improvement of the surface roughness.
【0006】熱延鋼板の成分 鋼成分はC:0.01〜0.15%、Si≦0.05
%、Mn≦0.9%、P≦0.04%、S=0.04
%、Al:0.015〜0.10%、N:0.0020
〜0.015%、残部Feおよび不可避的不純物より成
る。また、上記成分にNbを0.001〜0.02%加
えたものも好適に用いられる。以下に鋼成分の規制理由
を述べる。Cは0.01%より少なくなると結晶粒の粗
大化を招き、下限を0.01%とした。一方、0.15
%を越えると絞り加工性が劣化することから、範囲を
0.01〜0.15%とした。Siは缶用材料として耐
食性に有害な元素であるが、Alキルド鋼としては不可
避的に含有される元素であり、上限を0.05%とし
た。Mnは不純物であるSによる熱延中の赤熱脆性を防
止するために必要な成分であるが、一方0.9%を越え
ると絞り加工性を劣化することから上限を0.9%とし
た。Pは結晶粒微細化に有効な成分であり、また原板の
強度を高めることから一定の割合で添加されるが、一方
で耐食性を阻割する。本発明用途の缶用鋼板としてはP
が0.04%を越えると耐食性、特に耐孔明性が著しく
低下するため上限を0.04%とした。Sは熱延中の赤
熱脆性を生じる不純物成分であり、極力少ないことが望
ましいが、不可避的に含有される元素であり、上限を
0.04%とした。Alは製鋼に際し、脱酸剤として鋼
浴中に添加され、スラグとして除かれるが、添加量が少
ないと安定した脱酸効果が得られないため、0.015
%以上必要とする。またAlは固浴Nと反応してAlN
として析出し、結晶粒の細粒化に寄与する。一方で0.
10%を越える添加は技術上の効果が少なく、経済上好
ましくないので上限を0.10%とした。NはAlおよ
びNbと窒化物を形成し、細粒粒の細粒化に有効な成分
であるが、0.002%より少ないと窒化物との析出が
少なく、細粒化の効果がなくなり、一方0.015%を
越えるとスラブ表面に割れが生じ易く、構造欠陥になる
ため範囲を0.002〜0.015%とした。Nbは結
晶粒の細粒化に効果があり、固溶C、Nの低減に寄与す
る。0.001%より少ないと細粒化の効果がなく、一
方、0.020%を越えると固溶Nb量が増して逆に絞
り加工性の劣化を招くため上限を0.020%とした。Composition of hot rolled steel sheet Steel composition: C: 0.01-0.15%, Si ≦ 0.05
%, Mn ≦ 0.9%, P ≦ 0.04%, S = 0.04
%, Al: 0.015 to 0.10%, N: 0.0020
-0.015%, with the balance being Fe and unavoidable impurities. Further, those obtained by adding 0.001 to 0.02% of Nb to the above components are also preferably used. The reasons for the regulation of steel components are described below. When C is less than 0.01%, crystal grains become coarse, and the lower limit is made 0.01%. On the other hand, 0.15
%, The drawability deteriorates, so the range was made 0.01 to 0.15%. Si is an element harmful to corrosion resistance as a material for cans, but is an element inevitably contained in Al-killed steel, and the upper limit is 0.05%. Mn is a component necessary for preventing red-hot brittleness during hot rolling due to S as an impurity. On the other hand, if it exceeds 0.9%, drawability deteriorates, so the upper limit was made 0.9%. P is an effective component for refining the crystal grains, and is added at a certain ratio in order to increase the strength of the original sheet, but on the other hand, inhibits the corrosion resistance. P can be used as a steel sheet for cans of the present invention.
Exceeds 0.04%, the corrosion resistance, particularly the pitting resistance, is significantly reduced, so the upper limit was made 0.04%. S is an impurity component that causes red hot embrittlement during hot rolling, and is desirably as small as possible. However, S is an element inevitably contained, and the upper limit is set to 0.04%. Al is added to the steel bath as a deoxidizing agent during steel making and is removed as slag. However, if the added amount is small, a stable deoxidizing effect cannot be obtained.
% Or more is required. Al reacts with the solid bath N to form AlN.
And contribute to refinement of crystal grains. On the other hand, 0.
An addition exceeding 10% has little technical effect and is not economically preferable, so the upper limit was made 0.10%. N forms a nitride with Al and Nb and is an effective component for refining fine grains. However, if it is less than 0.002%, precipitation of the nitride is small, and the effect of refining is lost. On the other hand, if it exceeds 0.015%, cracks tend to occur on the slab surface, resulting in structural defects, so the range was made 0.002 to 0.015%. Nb is effective in refining crystal grains, and contributes to reduction of solid solution C and N. If it is less than 0.001%, there is no effect of grain refinement, while if it exceeds 0.020%, the amount of solute Nb increases and consequently the drawability deteriorates, so the upper limit was made 0.020%.
【0007】スラブ加熱温度、熱間圧延条件は、本発明
では特定するものではないが、スラブ加熱温度は、Nの
積極的分解固溶および熱間圧延温度の安定的確保の見地
から、1100℃以上とするのが望ましい。熱間圧延仕
上げ温度をAr3 点以下にすると、熱延板の結晶組織が
混粒化するとともに粗大化するので、熱間圧延仕上げ温
度はAr3 点以上とした。また巻取温度は熱延時のコイ
ル幅方向および長手方向の品質安定性を考慮して下限を
450℃とし、650℃を越えると結晶粒が粗大化し、
肌荒れが生じるため、巻取温度は450〜650℃の範
囲が望ましい。Although the slab heating temperature and the hot rolling conditions are not specified in the present invention, the slab heating temperature is set to 1100 ° C. from the viewpoint of the active decomposition of N and the stable securing of the hot rolling temperature. It is desirable to make the above. If the hot rolling finish temperature is lower than the Ar3 point, the crystal structure of the hot-rolled sheet is mixed and coarsened, so the hot rolling finish temperature is higher than the Ar3 point. In addition, the lower limit of the winding temperature is set to 450 ° C. in consideration of the quality stability in the coil width direction and the longitudinal direction at the time of hot rolling.
Since the skin becomes rough, the winding temperature is preferably in the range of 450 to 650 ° C.
【0008】冷間圧延工程 圧下率が75%未満では、焼鈍工程で鋼板の結晶粒粗大
化もしくは混粒化をもたらし、結晶粒を十分細粒化する
ことができないので、冷間圧延の圧下率は75%を下限
とすることが望ましい。[0008] If the rolling reduction is less than 75%, the annealing step results in coarsening or mixing of the grains of the steel sheet, and the grains cannot be sufficiently refined. Is preferably set to 75% as the lower limit.
【0009】焼鈍工程 本発明では、過時効処理を含むヒートサイクルでの焼鈍
を採用することにより、破胴に効果があることが判明し
た。これは固溶C、Nが低減したことによると考えられ
る。焼鈍は、連続焼鈍後、そのまま連続焼鈍処理で過時
効処理を行う場合と、一旦降温し、改めて箱焼鈍処理を
行う場合の、いずれの処理方法でもよい。前段階の連続
焼鈍の処理温度は、再結晶温度以上あれば良いが、75
0℃を越えると結晶粒の粗大化が起きるので好ましくな
い。なお、ここで言う過時効処理とは、一般の焼鈍処理
に比較して、低温、長時間での熱処理を言う。過時効処
理は連続焼鈍に続けて行う場合は、400〜550℃で
1〜3分間均熱処理を行う。400℃未満では、固溶
C、Nが低減できず、550℃を越えると結晶粒が粗大
化する。また、1分未満では、固溶C、Nの低減が十分
図れず、3分を越えると炉長が長大化するため、1〜3
分の範囲とする。また、過時効処理は、箱焼鈍でもよ
い。箱焼鈍による場合は、一旦下げた温度を400〜5
50℃に上げ、2〜10時間均熱処理を行う。400℃
未満では、過時効処理としての品質が安定せず、特性が
ばらつく。550℃を越えると、連続焼鈍と同様結晶粒
が粗大化する。2時間未満では、過時効処理としての品
質が安定せず、特性がばらつく。一方、10時間を越す
処理は経済上得策ではない。Annealing Step In the present invention, it has been found that the adoption of annealing in a heat cycle including overaging treatment has an effect on fracture. This is considered to be due to a decrease in solid solution C and N. Annealing may be carried out by any of the following methods: continuous aging followed by over-aging after continuous annealing, and case where the temperature is once lowered and box annealing is performed again. The treatment temperature of the continuous annealing in the preceding stage may be at least the recrystallization temperature,
If the temperature exceeds 0 ° C., the crystal grains become coarse, which is not preferable. Here, the overaging treatment means a heat treatment at a low temperature for a long time as compared with a general annealing treatment. When the overaging treatment is performed after the continuous annealing, the soaking is performed at 400 to 550 ° C for 1 to 3 minutes. If the temperature is lower than 400 ° C., solid solution C and N cannot be reduced. If the temperature exceeds 550 ° C., crystal grains become coarse. If the heating time is less than 1 minute, the solid solution C and N cannot be sufficiently reduced, and if the heating time exceeds 3 minutes, the furnace length becomes longer.
Minute range. The overaging treatment may be box annealing. In case of box annealing, lower the temperature once to 400 ~ 5.
The temperature is raised to 50 ° C., and the soaking is performed for 2 to 10 hours. 400 ° C
If it is less than 30, the quality as the overaging treatment is not stable, and the characteristics vary. If it exceeds 550 ° C., the crystal grains become coarse as in continuous annealing. If the time is less than 2 hours, the quality as the overaging treatment is not stable, and the characteristics vary. On the other hand, treatment exceeding 10 hours is not economically advantageous.
【0010】過時効処理の効果 一般に、固溶C、Nの増加により全伸びが低下し、一様
伸びも劣化する。これは、伸び時に発生するくびれや、
ボイドの連結機構に固溶C、Nが作用しているためと考
えられる。過時効処理は鋼中の固溶C、Nを低減させ、
鋼の軟質化に効果がある。過時効処理を行うことによ
り、鋼中固溶C、Nを低減させ、くびれの発生やボイド
の連結が抑制され、結果的に破断・破胴感受性を低減さ
せると考えられる。本発明の鋼成分範囲は、これらの過
時効処理における作用を発揮させる上で必要であって、
前記の各成分の作用はこの過時効処理を通じて達成され
るものである。C量の下限値やAl、Nb等の存在は結
晶粒の細粒化によって肌荒れ防止するが、特に、微量の
Nb添加はその固溶C、Nの低減作用を過時効処理と相
俟つて発揮することにより加工性を向上する。[0010] In general, the effect of overage treatment decreases the total elongation and the uniform elongation by increasing the amount of solid solution C and N. This is due to the constriction that occurs when stretching,
This is probably because solid solution C and N act on the connection mechanism of the voids. Overaging treatment reduces solid solution C and N in steel,
Effective for softening steel. It is considered that by performing the overaging treatment, the solid solution C and N in the steel are reduced, the occurrence of constriction and the connection of voids are suppressed, and as a result, the susceptibility to breakage and rupture is reduced. The steel component range of the present invention is necessary for exerting the action in these overaging treatments,
The action of each of the above components is achieved through this overaging treatment. The lower limit of the amount of C and the presence of Al, Nb, etc. prevent the roughening of the crystal grains by grain refinement. In particular, the addition of a small amount of Nb exhibits the effect of reducing the solute C and N in combination with the overaging treatment. By doing so, the workability is improved.
【0011】調質圧延 調質圧延(SR,Single Reduce Rol
lingの略)は、伸び率が0.5〜2.0%の範囲で
あれば、ストレッチャストレインの発生が防止されるた
め、この範囲が適当である。本発明では、過時効処理に
より前記の鋼中の固溶C、Nを低減してくびれの発生や
ボイドの連結を抑制して深絞りにおける加工性を向上し
て、本発明の対象である薄肉化深絞りの加工条件を満た
すと共に、伸び率が0.5〜2.0%の範囲の調質圧延
を行うことによって強度を付与し、これによって、本発
明の鋼板は、薄肉化深絞り加工に求められる高度の加工
性に併せて加工時の破胴発生を生じない板強度を付与す
ることができる。このように、本発明においては、これ
ら2つの工程が組み合わされて、加工性と板強度それぞ
れの条件を達成することができる。また、この調質圧延
によって極薄厚の缶において求められる所要の缶強度を
も達成するものである。Temper Rolling Temper rolling (SR, Single Reduce Roll
(Ling is an abbreviation for ling), since the occurrence of stretcher strain is prevented if the elongation percentage is in the range of 0.5 to 2.0%. In the present invention, the over-aging treatment reduces the solid solution C and N in the steel, suppresses the occurrence of constriction and the connection of voids, improves the workability in deep drawing, and reduces the thickness of the thin object which is the object of the present invention. In addition to satisfying the processing conditions for deep drawing, the steel sheet of the present invention is given a strength by performing temper rolling in an elongation range of 0.5 to 2.0%. In addition to the high workability required for the steel sheet, it is possible to impart a plate strength that does not cause the occurrence of a broken body during processing. As described above, in the present invention, these two steps can be combined to achieve the respective conditions of workability and plate strength. The temper rolling also achieves the required can strength required for extremely thin cans.
【0012】DR圧延 DR圧延は、特に成形後の缶強度をもたせる場合に行う
ことがあるが、圧下率は20〜50%とする。20%未
満では、十分な缶強度が得られず、50%を越えると鋼
板が高強度となり、缶成形加工に困難を来す。ここでD
R圧延とは、Double Reduce Rolli
ng の略であり、調質圧延よりも、より積極的に板厚
を減少させ、板強度を増加させる圧延法である。本発明
では、上記調質圧延とDR圧延とを含めて、二次冷延と
する。DR Rolling DR rolling is sometimes performed particularly when the strength of the can is increased after forming. The rolling reduction is set to 20 to 50%. If it is less than 20%, sufficient can strength cannot be obtained, and if it exceeds 50%, the steel sheet has high strength, and it becomes difficult to form a can. Where D
R Rolling is Double Reduce Rolli
ng, which is a rolling method in which the sheet thickness is more positively reduced and the sheet strength is increased more than in temper rolling. In the present invention, secondary cold rolling is performed including the temper rolling and the DR rolling.
【0013】つぎに、本発明に用いられる鋼板として
は、シ−ト状およびコイル状の鋼板、鋼箔およびそれら
の鋼板等に表面処理を施したものがあげられる。特に、
下層が金属クロム、上層がクロム水和酸化物の2層構造
をもつ電解クロム酸処理鋼板あるいは極薄錫めっき鋼
板、ニッケルめっき鋼板、亜鉛めっき鋼板およびこれら
のめっき鋼板にクロム水和酸化物あるいは上層がクロム
水和酸化物、下層が金属クロム層からなる2層構造をも
つ表面処理をほどこしたものがポリエステル樹脂との接
触性に優れている。Next, examples of the steel sheet used in the present invention include sheet-shaped and coil-shaped steel sheets, steel foils, and those obtained by subjecting these steel sheets to surface treatment. Especially,
Electrolytic chromic acid-treated steel sheet or ultra-thin tin-plated steel sheet, nickel-plated steel sheet, zinc-plated steel sheet having a two-layer structure of chromium metal on the lower layer and hydrated chromium oxide on the upper layer Is a hydrated oxide of chromium, and a surface treatment having a two-layer structure of a metal chromium layer as the lower layer is excellent in contact with the polyester resin.
【0014】平均結晶粒径 結晶粒径の特定について図1および図2に基づいて説明
する。図1は平均結晶粒径と製缶加工後の缶側壁の肌荒
れ性との関係を示したものである。図1から平均結晶粒
径が大きくなると製缶加工後の表面の肌荒れ性が劣化す
ることがわかる。平均結晶粒径が6μmを越えると、表
面の肌荒れ性が劣化し、缶としての見栄えや特性が損な
われる。このため平均結晶粒径は6μmを越えないこと
とする。また図2は平均結晶粒径と耐食性との関係を示
したものである。図2からも平均結晶粒径が6μmを越
えない範囲で耐食性がよいことがわかる。なお、耐食性
の評価は次のようにした。製缶加工後の缶を130℃で
20分の熱処理を行い、水を充填し、37℃、2週間経
時後の缶内面の腐食(黒化)程度を目視で評価した。Average Grain Size The specification of the crystal grain size will be described with reference to FIGS. FIG. 1 shows the relationship between the average crystal grain size and the roughness of the side wall of the can after the can-making process. From FIG. 1, it can be seen that when the average crystal grain size is large, the surface roughness after the can-making process is deteriorated. When the average crystal grain size exceeds 6 μm, the surface roughness is deteriorated, and the appearance and characteristics as a can are impaired. For this reason, the average crystal grain size does not exceed 6 μm. FIG. 2 shows the relationship between the average crystal grain size and the corrosion resistance. FIG. 2 also shows that the corrosion resistance is good when the average crystal grain size does not exceed 6 μm. In addition, evaluation of corrosion resistance was performed as follows. After the can-making process, the can was heat-treated at 130 ° C. for 20 minutes, filled with water, and the degree of corrosion (blackening) of the inner surface of the can after 2 weeks at 37 ° C. was visually evaluated.
【0015】[0015]
【0016】[0016]
【表1】 [Table 1]
【0017】[0017]
【表2】 [Table 2]
【0018】評価 本発明の実施例No.1〜6は本発明の成分範囲内で、
過時効処理を実施しており加工性に優れている。表2に
示すとおり平均結晶粒径が6.0μm以下であり、肌荒
れ性、耐食性とも優れていることが判る。また、本発明
の薄肉化深絞り缶用途として重要な加工性においても優
れた結果となっている。特に実施例No.5及び6は微量
のNb添加により加工性に優れていることが判る。一
方、比較例No.7はC量が本発明範囲の下限以下で少な
いため結晶粒が粗大となり肌荒れ性、耐食性共に不良と
なり、過時効処理を施したにもかかわらず加工性におい
ても劣った結果となっている。比較例No.8〜10は、
発明の成分範囲にあるが、過時効処理を実施しておらず
加工性が劣っている。なおここで、評価缶は、それぞれ
以下のようにした。肌荒れ性の評価は、薄肉化深絞り缶
成形後の缶内面の缶側壁の表面粗さを測定し、Raが1
μm以下を◎(最良)とし、1〜1.5μmのものを○
(良)とし、1.5〜2μmのものを△(やや不良)と
し、2μm以上を×(不良)として評価した。また、耐
食性の評価は、薄肉化深絞り缶成形後、130℃×20
分の熱処理を行い、水を充填し、37℃で2週間経時後
の缶内面の腐食(黒化)程度を目視で評価した。表面が
全く黒化していないものを◎(最良)とし、黒化の程度
が微小なものを○(良)とし、黒化の範囲が小のもの
(直径5mm以下)を△(やや不良)とし、大(直径5
mm以上)のものを×(不良)として評価した。加工性
の評価は、薄肉化深絞り缶成形時にしわ押さえ圧を上げ
ていって、破胴するまでのしわ押さえ圧の大小で評価し
た。しわ押さえ圧が5トン以下で破胴したものを△(や
や不良)とし、5〜7トンで破胴したものを○(良)と
し、7トン以上で破胴したものを◎(最良)とした。Evaluation Example No. of the present invention 1 to 6 are within the range of the component of the present invention,
Excellent workability due to overaging treatment. As shown in Table 2, the average crystal grain size was 6.0 μm or less, and it was found that both the surface roughness and the corrosion resistance were excellent. In addition, excellent results are obtained in workability, which is important for the use of the thinned deep drawn can of the present invention. In particular, it can be seen that Examples Nos. 5 and 6 are excellent in workability by adding a small amount of Nb. On the other hand, in Comparative Example No. 7, since the C content was less than the lower limit of the range of the present invention, the crystal grains were coarse, the surface roughness and corrosion resistance were poor, and the workability was poor despite the overaging treatment. It has become. Comparative Examples No. 8 to 10
Although it is within the range of the components of the invention, it has not been overaged and has poor processability. Here, the evaluation cans were as follows. The evaluation of the roughness was measured by measuring the surface roughness of the inner wall of the can after molding the thinned deep drawn can.
μm or less is marked as ◎ (best), and 1 to 1.5 μm is marked as ○
(Good), 1.5 to 2 μm was evaluated as Δ (Slightly poor), and 2 μm or more was evaluated as × (Defective). The corrosion resistance was evaluated at 130 ° C. × 20 after forming a thinned deep drawn can.
For 2 minutes, filled with water, and visually evaluated for the degree of corrosion (blackening) of the inner surface of the can after elapse of 2 weeks at 37 ° C. ◎ (best) when the surface was not blackened at all, ○ (good) when the degree of blackening was minute, and Δ (slightly poor) when the degree of blackening was small (diameter of 5 mm or less). , Large (diameter 5
mm or more) was evaluated as x (defective). The workability was evaluated by increasing the wrinkle holding pressure at the time of forming a thin-walled deep-drawing can, and evaluating the magnitude of the wrinkle holding pressure until breaking.も の (slightly poor) when the wrinkle pressing pressure was 5 tons or less, ○ (good) when 5 to 7 tons were broken, and ◎ (best) when 7 tons or more were broken did.
【0019】[0019]
【発明の効果】本発明により、肌荒れ性、耐食性に優
れ、連続高速製缶加工時においても破胴が起きず、しか
も加工性に優れた薄肉化深絞り缶用途に適した鋼板を提
供することができる。なお、本発明により提供される鋼
板は、缶用途として、鋼板単独でも使用可能であるが、
この鋼板に表面処理をして、ぶりき、TFS、ニッケル
めっき鋼板等としても利用できる。さらに、上記の表面
処理鋼板にポリエステル等の樹脂フィルムを被覆しても
よい。また、この鋼板にエポキシ等の塗料をコーティン
グしたものも薄肉化深絞り缶用途に適用できる。According to the present invention, there is provided a steel sheet which is excellent in surface roughness and corrosion resistance, does not break even during continuous high-speed can-making, and is excellent in workability and is suitable for a thin-walled deep drawn can. Can be. In addition, the steel sheet provided by the present invention can be used as a can for a steel sheet alone,
This steel sheet can be surface-treated and used as tinplate, TFS, nickel-plated steel sheet and the like. Further, the surface-treated steel sheet may be covered with a resin film such as polyester. Further, a steel sheet coated with a paint such as epoxy can also be used for thinned deep drawing cans.
【図1】肌荒れ性に及ぼす平均結晶粒径の影響を示すグ
ラフである。FIG. 1 is a graph showing the influence of an average crystal grain size on skin roughness.
【図2】耐食性に及ぼす平均結晶粒径の影響を示すグラ
フである。FIG. 2 is a graph showing the effect of average crystal grain size on corrosion resistance.
Claims (4)
05%、Mn≦0.9%、P≦0.04%、S≦0.0
4%、Al:0.015〜0.10%、N:0.002
0〜0.015%、残部Feおよび不可避的不純物から
なる熱延鋼板を、冷間圧延、過時効処理を含むヒートサ
イクルでの焼鈍、伸び率0.5〜2.0%での調質圧
延、を順次行い、調質圧延後の鋼板の平均結晶粒径が
6.0μm以下である薄肉化深絞り缶用途に適した鋼
板。1. C: 0.01 to 0.15%, Si ≦ 0.
05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦ 0.0
4%, Al: 0.015 to 0.10%, N: 0.002
A hot-rolled steel sheet comprising 0 to 0.015%, the balance being Fe and unavoidable impurities, is subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%. , In order that the average grain size of the steel sheet after temper rolling is 6.0 μm or less, which is suitable for thinning deep drawing cans.
05%、Mn≦0.9%、P≦0.04%、S≦0.0
4%、Al:0.015〜0.10%、N:0.002
0〜0.015%、Nb:0.001〜0.020%、
残部Feおよび不可避的不純物からなる熱延鋼板を、冷
間圧延、過時効処理を含むヒートサイクルでの焼鈍、伸
び率0.5〜2.0%での調質圧延、を順次行い、調質
圧延後の鋼板の平均結晶粒径が6.0μm以下である薄
肉化深絞り缶用途に適した鋼板。2. C: 0.01 to 0.15%, Si ≦ 0.
05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦ 0.0
4%, Al: 0.015 to 0.10%, N: 0.002
0 to 0.015%, Nb: 0.001 to 0.020%,
The hot-rolled steel sheet consisting of the balance of Fe and unavoidable impurities is sequentially subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%. A steel sheet suitable for use in a thin-walled deep-drawing can having an average crystal grain size of 6.0 μm or less after rolling.
05%、Mn≦0.9%、P≦0.04%、S≦0.0
4%、Al:0.015〜0.10%、N:0.002
0〜0.015%、残部Feおよび不可避的不純物から
なる熱延鋼板を、冷間圧延、過時効処理を含むヒートサ
イクルでの連続焼鈍、伸び率0.5〜2.0%での調質
圧延、を順次行う薄肉化深絞り缶用途に適した鋼板の製
造法。3. C: 0.01 to 0.15%, Si ≦ 0.
05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦ 0.0
4%, Al: 0.015 to 0.10%, N: 0.002
Hot-rolled steel sheet consisting of 0 to 0.015%, balance Fe and unavoidable impurities, cold-rolled, continuously annealed in a heat cycle including overaging treatment, tempering at an elongation of 0.5 to 2.0% A method for producing a steel sheet suitable for thinning deep-drawing cans, in which rolling and rolling are sequentially performed.
05%、Mn≦0.9%、P≦0.04%、S≦0.0
4%、Al:0.015〜0.10%、N:0.002
0〜0.015%、Nb:0.001〜0.020%、
残部Feおよび不可避的不純物からなる熱延鋼板を、冷
間圧延、過時効処理を含むヒートサイクルでの焼鈍、伸
び率0.5〜2.0%での調質圧延、を順次行う薄肉化
深絞り缶用途に適した鋼板の製造法。4. C: 0.01 to 0.15%, Si ≦ 0.
05%, Mn ≦ 0.9%, P ≦ 0.04%, S ≦ 0.0
4%, Al: 0.015 to 0.10%, N: 0.002
0 to 0.015%, Nb: 0.001 to 0.020%,
A hot-rolled steel sheet comprising the balance of Fe and unavoidable impurities is subjected to cold rolling, annealing in a heat cycle including overaging treatment, and temper rolling at an elongation of 0.5 to 2.0%, in order. A method for producing steel sheets suitable for drawing cans.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP10077097A JPH1030152A (en) | 1997-04-04 | 1997-04-04 | Steel sheet suitable for use in thin deep-drawn can, and its production |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP10077097A JPH1030152A (en) | 1997-04-04 | 1997-04-04 | Steel sheet suitable for use in thin deep-drawn can, and its production |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
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JP5197825A Division JP2676581B2 (en) | 1993-07-14 | 1993-07-14 | Steel sheet suitable for thinned deep-drawing can and its manufacturing method |
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Publication Number | Publication Date |
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JPH1030152A true JPH1030152A (en) | 1998-02-03 |
Family
ID=14282733
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JP2006045590A (en) * | 2004-07-30 | 2006-02-16 | Toyo Kohan Co Ltd | Steel sheet coated with organic resin film for di can, and manufacturing method therefor |
JP2016130361A (en) * | 2015-01-09 | 2016-07-21 | Jfeスチール株式会社 | Steel sheet for can and method for manufacturing steel sheet for can |
WO2024082755A1 (en) * | 2022-10-17 | 2024-04-25 | 江苏省沙钢钢铁研究院有限公司 | Tin plate and manufacturing method therefor |
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1997
- 1997-04-04 JP JP10077097A patent/JPH1030152A/en active Pending
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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US6974511B1 (en) * | 1999-07-01 | 2005-12-13 | Sollac | Steel sheet with low aluminum content for containers |
JP2006045590A (en) * | 2004-07-30 | 2006-02-16 | Toyo Kohan Co Ltd | Steel sheet coated with organic resin film for di can, and manufacturing method therefor |
JP2016130361A (en) * | 2015-01-09 | 2016-07-21 | Jfeスチール株式会社 | Steel sheet for can and method for manufacturing steel sheet for can |
WO2024082755A1 (en) * | 2022-10-17 | 2024-04-25 | 江苏省沙钢钢铁研究院有限公司 | Tin plate and manufacturing method therefor |
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