JP2688312B2 - High strength and high toughness steel plate - Google Patents
High strength and high toughness steel plateInfo
- Publication number
- JP2688312B2 JP2688312B2 JP4858993A JP4858993A JP2688312B2 JP 2688312 B2 JP2688312 B2 JP 2688312B2 JP 4858993 A JP4858993 A JP 4858993A JP 4858993 A JP4858993 A JP 4858993A JP 2688312 B2 JP2688312 B2 JP 2688312B2
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Description
【0001】[0001]
【産業上の利用分野】本発明は高強度高靭性鋼板に関
し、さらに詳しくは、低温で使用される船舶、海洋構造
物、ラインパイプ、低温用タンクまたは橋梁等の溶接構
造物に使用され、溶接性および溶接熱影響部の靭性(C
TOD特性)の優れた高強度高靭性鋼板に関するもので
ある。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-strength and high-toughness steel plate, and more particularly, it is used for welding structures such as ships, marine structures, line pipes, low-temperature tanks or bridges which are used at low temperatures, and are welded. And toughness of weld heat affected zone (C
The present invention relates to a high strength and high toughness steel sheet having excellent TOD characteristics).
【0002】[0002]
【従来技術】従来より、高強度であり、かつ、溶接性に
優れている鋼板としては、Cu析出強化型高張力鋼板が
よく知られている。例えば、米国特許第3692514
号明細書に具体的に説明されており、さらに、ASTM
規格A710において規定されている。2. Description of the Related Art Conventionally, a Cu precipitation strengthened high-strength steel sheet is well known as a steel sheet having high strength and excellent weldability. For example, US Pat. No. 3,692,514.
And the ASTM
It is specified in Standard A710.
【0003】しかしながら、最近になって構造物が大型
化し、さらに、使用環境が苛酷になってきているのに伴
い、使用される鋼材に対して要求される特性は極めて厳
しくなってきている。特に、構造物の安全性確保のため
に、良好な母材靭性を有すると共に、最も脆化の激しい
溶接継手部に高靭性が要求されている。However, with the recent increase in the size of structures and the harsh environment of use, the characteristics required for the steel materials used have become extremely severe. In particular, in order to secure the safety of the structure, it is required that the welded joint portion having good base metal toughness and the most brittle is highly tough.
【0004】そして、破壊靭性評価の定量的な方法とし
て溶接熱影響部の靭性(CTOD特性)試験があり、安
全を重要視する構造物においてはシャルピー衝撃特性よ
りも現実に即した破壊靭性の評価が可能な溶接熱影響部
の靭性(CTOD特性)が要求されるのである。As a quantitative method for evaluating fracture toughness, there is a toughness (CTOD characteristic) test of a weld heat affected zone, and in a structure in which safety is important, the fracture toughness evaluation is more realistic than the Charpy impact characteristic. That is, the toughness (CTOD characteristic) of the weld heat affected zone is required.
【0005】しかし、高強度鋼板の溶接継手部では多層
盛溶接を行った時に、局所脆化域が生成し、この局所脆
化域が破壊の起点となり、溶接熱影響部の靭性(CTO
D特性)を低下させるため、良好な溶接熱影響部の靭性
(CTOD特性)を安定に確保することは困難であっ
た。However, in the welded joint portion of a high strength steel sheet, a local embrittlement region is generated when multi-pass welding is performed, and this local embrittlement region becomes a starting point of fracture, resulting in a toughness (CTO) of the heat affected zone of welding.
It is difficult to stably secure good toughness (CTOD characteristics) of the heat-affected zone of the welding because it lowers the D characteristics).
【0006】一般的に、溶接継手部の溶接熱影響部の靭
性(CTOD特性)を向上させるためには、島状マルテ
ンサイト(M−A)を低減することが重要であるといわ
れており、この島状マルテンサイト(M−A)を低減す
るために、炭素当量を低減するのが効果的であり、Cは
0.10wt%以下、Nbは有害元素として、通常、0.
02wt%未満に抑制する必要があるとされている。し
かし、低炭素当量、低炭素、かつ、低Nb含有量では、
鋼板の高強度化、高靭性化、溶接部の高い溶接熱影響部
の靭性(高CTOD特性)を全て達成することは困難で
ある。It is generally said that it is important to reduce island martensite (MA) in order to improve the toughness (CTOD property) of the weld heat affected zone of the welded joint. In order to reduce the island-like martensite (MA), it is effective to reduce the carbon equivalent, C is 0.10 wt% or less, and Nb is a harmful element, usually 0.1.
It is said that it is necessary to suppress it to less than 02 wt%. However, at low carbon equivalent, low carbon, and low Nb content,
It is difficult to achieve all of high strength and high toughness of a steel sheet and high toughness (high CTOD characteristics) of a weld heat affected zone of a welded part.
【0007】[0007]
【発明が解決しようとする課題】本発明は上記に説明し
たように、従来における大型構造物に使用する鋼材にお
ける種々の特性を達成することができないという問題点
を解決するために本発明者が鋭意研究を行い、検討を重
ねた結果、鋼板を低炭素当量で、かつ、高強度化するた
めには、Cuの析出強化を利用することが効果的である
ことがわかった。SUMMARY OF THE INVENTION As described above, the present invention has been made by the present inventor in order to solve the problem that various characteristics of conventional steel materials used for large structures cannot be achieved. As a result of intensive studies and studies, it has been found that it is effective to utilize Cu precipitation strengthening in order to increase the strength of the steel sheet at a low carbon equivalent.
【0008】しかし、C≦0.10wt%、Nb<0.0
2wt%の条件においては、Cuの析出強化を利用して
も、高強度、高靭性、および、溶接継手部の良好な溶接
熱影響部の靭性(CTOD特性)を確保することは困難
であり、従って、Nbを積極的に活用して、さらに、溶
接熱影響部の靭性(CTOD特性)に有害な要因を除去
することが必要である。However, C ≦ 0.10 wt%, Nb <0.0
Under the condition of 2 wt%, it is difficult to secure high strength, high toughness, and good weld heat affected zone toughness (CTOD characteristics) of the welded joint, even if Cu precipitation strengthening is utilized. Therefore, it is necessary to positively utilize Nb to further remove a factor harmful to the toughness (CTOD characteristic) of the heat-affected zone of welding.
【0009】そして、Nb<0.02wt%の必要性は
C>0.06wt%の比較的にC含有量の多い場合であ
り、C含有量を0.06wt%以下にまで低減した場合
には、Nb含有量を0.02wt%以上に増大させて
も、多層盛溶接では島状マルテンサイト(M−A)の生
成は少なく、優れた溶接熱影響部の靭性(CTOD特
性)が得られることが判明した。The necessity of Nb <0.02 wt% is the case where the C content is relatively high such that C> 0.06 wt%, and when the C content is reduced to 0.06 wt% or less. , Even if the Nb content is increased to 0.02 wt% or more, the formation of island martensite (MA) is small in the multi-pass welding and excellent toughness (CTOD characteristics) of the heat affected zone can be obtained. There was found.
【0010】特に、C≦0.06wt%、Nb≧0.02
wt%の含有量とすることにより、1200℃以上の温
度に加熱された溶接熱影響部の組織が、低靭性である粗
粒な上部ベイナイト組織とはならず、フェライトを含有
している、より微細な組織となるため、この組織自体が
高靭性を示し、さらに、2回目の熱サイクルにより2相
域に加熱された部分でも、島状マルテンサイト(M−
A)が少なく、溶接熱影響部の高靭性(高CTOD特
性)が得られるのである。In particular, C ≦ 0.06 wt%, Nb ≧ 0.02
By setting the content to be wt%, the structure of the weld heat affected zone heated to a temperature of 1200 ° C. or higher does not become a coarse grained upper bainite structure having low toughness, and contains ferrite. Since the structure becomes a fine structure, the structure itself exhibits high toughness, and even in the portion heated to the two-phase region by the second thermal cycle, island martensite (M-
A) is small, and high toughness (high CTOD characteristics) of the weld heat affected zone can be obtained.
【0011】また、Nbを0.02wt%以上含有させ
ることにより、鋼板の組織を極めて微細なフェライト
(アシキュラーフェライト、ポリゴナルフェライトの1
種または2種)を主とする組織とすることができる。そ
して、鋼板中のNb炭窒化物とTiNの微細析出物およ
び鋼板の微細なフェライトを主とする組織は、加熱オー
ステナイト粒径の粗大化を防止し、溶接熱影響部の靭性
(CTOD特性)を向上させる効果がある。Further, by containing 0.02 wt% or more of Nb, the structure of the steel sheet is extremely fine ferrite (acicular ferrite, polygonal ferrite 1).
It can be a tissue mainly composed of two or more species. The structure mainly composed of fine precipitates of Nb carbonitride and TiN in the steel sheet and fine ferrite of the steel sheet prevents coarsening of the heated austenite grain size and improves the toughness (CTOD characteristic) of the weld heat affected zone. Has the effect of improving.
【0012】さらに、このような成分調整と鋼板の組織
の微細化だけでは、良好な溶接熱影響部の靭性(CTO
D特性)を安定して確保することが困難であり、この原
因は、中心偏析部或いは介在物が破壊発生の起点となる
ことにあると判明した。この中心偏析部は成分が濃化し
た部分であるから、溶接後の組織が硬化して島状マルテ
ンサイト(M−A)の増加等により靭性が劣化する。従
って、中心偏析部においてもC含有量を0.06wt%
以下、P含有量を0.015wt%以下になるように中
心偏析を減らす必要がある。Further, only by adjusting the composition and refining the structure of the steel sheet, the toughness of the weld heat affected zone (CTO) can be improved.
It has been found that it is difficult to stably secure the (D characteristic), and the cause is that the center segregation portion or inclusions become the starting point of fracture occurrence. Since this central segregation portion is a portion where the components are concentrated, the structure after welding is hardened and the toughness deteriorates due to an increase in island martensite (MA) and the like. Therefore, the C content in the center segregation portion is 0.06 wt%
Hereinafter, it is necessary to reduce the center segregation so that the P content is 0.015 wt% or less.
【0013】また、破壊が発生する起点となる介在物
は、主として長く連なったAl2O3(アルミナ)系の介
在物であり、展伸したMnS等のA系介在物の場合もあ
る。この介在物が、厚さ10μm以上で、かつ、長さ5
0μm以上の場合には、破壊発生の起点となる可能性の
あることがわかった。Also, the inclusions which are the starting points of the fractures are mainly Al 2 O 3 (alumina) -based inclusions that are continuous for a long time, and there are cases where expanded A-based inclusions such as MnS. This inclusion has a thickness of 10 μm or more and a length of 5
It has been found that when the thickness is 0 μm or more, it may be a starting point of fracture occurrence.
【0014】また、Caの含有はMnS等のA系介在物
の形態制御に極めて有効であるが、Caはさらに破壊靭
性に有害なアルミナ系介在物の量を低減し、アルミナ系
介在物を微細化する作用を有することが明らかとなり、
Caの含有により溶接継手部の溶接熱影響部の靭性(C
TOD特性)が向上することが判明した。本発明は上記
に説明した種々の知見に基づいて、高強度高靭性鋼板を
開発したのである。Further, although the inclusion of Ca is extremely effective in controlling the morphology of A-based inclusions such as MnS, Ca further reduces the amount of alumina-based inclusions that are detrimental to fracture toughness, and makes the alumina-based inclusions finer. It is clear that it has the effect of
Due to the inclusion of Ca, the toughness (C
It was found that the TOD characteristic) was improved. The present invention has developed a high strength and high toughness steel sheet based on the various findings described above.
【0015】[0015]
【課題を解決するための手段】C 0.01〜0.06w
t%、Si 0.01〜0.50wt%、Mn 0.5〜
2.0wt%、P ≦ 0.015wt%、S ≦ 0.
005wt%、Al 0.01〜0.05wt%、Cu
0.6〜2.0wt%、Ni 0.3〜3.5wt%、Nb
0.02〜0.05wt%、Ti 0.005〜0.02
wt%、N 0.003〜0.008wt%、Ca 0.
0005〜0.0030wt%を含有し、残部Feおよ
び不可避不純物からなり、かつ、鋼板の中心偏析部(板
厚/50)mm厚×10mm×10mmの平均化学分析
値がC ≦ 0.06wt%、P ≦ 0.015wt%
であり、断面で観察される厚さ10μm以上、長さ50
μm以上の介在物が10mm2内に1個以下、鋼板の組
織が粒径20μm以下のアシキュラーフェライト、また
は、ポリゴナルフェライトを合計40%以上含有されて
いることを特徴とする高強度高靭性鋼板を第1の発明と
し、C 0.01〜0.06wt%、Si 0.01〜0.
50wt%、Mn 0.5〜2.0wt%、P ≦ 0.
015wt%、S ≦ 0.005wt%、Al 0.0
1〜0.05wt%、Cu 0.6〜2.0wt%、Ni
0.3〜3.5wt%、Nb 0.02〜0.05wt
%、Ti 0.005〜0.02wt%、N 0.003
〜0.008wt%、Ca 0.0005〜0.0030
wt%を含有し、さらに、Cr 0.01〜0.50wt
%、Mo 0.01〜0.50wt%、V 0.005〜
0.10wt%の内から選んだ1種または2種以上を含
有し、かつ、REM 0.005〜0.050wt%を含
有し、残部Feおよび不可避不純物からなり、かつ、鋼
板の中心偏析部(板厚/50)mm厚×10mm×10
mmの平均化学分析値がC ≦ 0.06wt%、P
≦ 0.015wt%であり、断面で観察される厚さ1
0μm以上、長さ50μm以上の介在物が10mm2内
に1個以下、鋼板の組織が粒径20μm以下のアシキュ
ラーフェライト、または、ポリゴナルフェライトを合計
40%以上含有されていることを特徴とする高強度高靭
性鋼板を第2の発明とする2つの発明よりなるものであ
る。[Means for Solving the Problems] C 0.01 to 0.06w
t%, Si 0.01 to 0.50 wt%, Mn 0.5 to
2.0 wt%, P ≤ 0.015 wt%, S ≤ 0.0.
005wt%, Al 0.01-0.05wt%, Cu
0.6-2.0 wt%, Ni 0.3-3.5 wt%, Nb
0.02 to 0.05 wt%, Ti 0.005 to 0.02
wt%, N 0.003 to 0.008 wt%, Ca 0.0.
0005 to 0.0030 wt%, the balance Fe and unavoidable impurities, and the average chemical analysis value of the central segregated portion (sheet thickness / 50) mm thickness x 10 mm x 10 mm of the steel sheet is C ≤ 0.06 wt%, P ≤ 0.015 wt%
And a thickness of 10 μm or more and a length of 50 observed on the cross section.
High strength and high toughness characterized by containing 1 or less inclusions of 10 μm or more in 10 mm 2 and acicular ferrite having a grain size of 20 μm or less or polygonal ferrite in a total content of 40% or more. A steel sheet is the first invention, C 0.01 to 0.06 wt%, Si 0.01 to 0.0.
50 wt%, Mn 0.5-2.0 wt%, P ≤ 0.0.
015 wt%, S ≤ 0.005 wt%, Al 0.0
1-0.05wt%, Cu 0.6-2.0wt%, Ni
0.3-3.5 wt%, Nb 0.02-0.05 wt
%, Ti 0.005 to 0.02 wt%, N 0.003
~ 0.008 wt%, Ca 0.0005 ~ 0.0030
wt%, Cr 0.01-0.50 wt%
%, Mo 0.01 to 0.50 wt%, V 0.005
It contains one or more selected from 0.10 wt%, and contains REM 0.005-0.050 wt%, consists of the balance Fe and inevitable impurities, and has a central segregation part ( Plate thickness / 50) mm thickness x 10 mm x 10
The average chemical analysis value of mm is C ≤ 0.06 wt%, P
≤ 0.015 wt%, thickness observed in cross section 1
One or less inclusions having a size of 0 μm or more and a length of 50 μm or more in 10 mm 2 , and a steel sheet structure containing acicular ferrite having a grain size of 20 μm or less or polygonal ferrite in a total content of 40% or more. And a high strength and high toughness steel sheet according to the second invention.
【0016】本発明に係る高強度高靭性鋼板について、
以下詳細に説明する。先ず、本発明に係る高強度高靭性
鋼板の含有成分および成分割合について説明する。Regarding the high strength and high toughness steel plate according to the present invention,
This will be described in detail below. First, the contained components and component ratios of the high strength and high toughness steel sheet according to the present invention will be described.
【0017】Cは溶接継手熱影響部において島状マルテ
ンサイト(M−A)の量を増加させるため、溶接熱影響
部の靭性(CTOD特性)に有害であると共に、溶接性
を阻害するために少ない含有量であることが望ましく、
含有量が0.01wt%未満では強度を確保することが
できず、また、0.06wt%を越えて含有させると溶
接部の組織および鋼板母材の組織が低靭性の上部ベイナ
イト組織を多く含むようになり、溶接部の島状マルテン
サイト(M−A)の量が多くなり過ぎる。よって、C含
有量は0.01〜0.06wt%とする。Since C increases the amount of island martensite (MA) in the heat affected zone of the welded joint, it is harmful to the toughness (CTOD characteristic) of the heat affected zone and also impairs the weldability. It is desirable that the content is small,
If the content is less than 0.01 wt%, the strength cannot be secured, and if the content exceeds 0.06 wt%, the weld microstructure and the steel plate base metal microstructure include a large amount of a low toughness upper bainite microstructure. As a result, the amount of island martensite (MA) in the weld becomes too large. Therefore, the C content is set to 0.01 to 0.06 wt%.
【0018】Siは鋼の脱酸と強化に対して有用な元素
であり、含有量が0.01wt%未満ではこのような効
果は少なく、また、0.50wt%を越えて含有させる
と溶接性および靭性が劣化する。よって、Si含有量は
0.01〜0.50wt%とする。Si is a useful element for deoxidation and strengthening of steel, and if the content is less than 0.01 wt%, such an effect is small, and if it exceeds 0.50 wt%, weldability is obtained. And toughness deteriorates. Therefore, the Si content is set to 0.01 to 0.50 wt%.
【0019】Mnは強度を上昇させるために有用な元素
であり、含有量が0.5wt%未満ではこの効果は少な
く、また、2.0wt%を越えて含有させると溶接性が
劣化する。よって、Mn含有量は0.5〜2.0wt%と
する。Mn is an element useful for increasing the strength, and if the content is less than 0.5 wt%, this effect is small, and if it exceeds 2.0 wt%, the weldability deteriorates. Therefore, the Mn content is set to 0.5 to 2.0 wt%.
【0020】Pは偏析し易い元素であり、粒界に偏析し
て靭性を劣化させる。よって、P含有量は0.015w
t%以下とする。P is an element that easily segregates and segregates at grain boundaries to deteriorate toughness. Therefore, the P content is 0.015w
t% or less.
【0021】SはMnSを生成して、溶接熱影響部の試
験(CTOD試験)における破壊の起点となる。よっ
て、S含有量は0.005wt%以下とする。S forms MnS and becomes a starting point of fracture in the welding heat affected zone test (CTOD test). Therefore, the S content is set to 0.005 wt% or less.
【0022】Alは脱酸元素であり、含有量ば0.01
wt%未満ではこの効果は少なく、また、0.05wt
%を越えて過剰に含有させるとアルミナ系の粗大な介在
物を生成して、靭性を劣化させる。よって、Al含有量
は0.01〜0.05wt%とする。Al is a deoxidizing element and its content is 0.01
If it is less than wt%, this effect is small, and 0.05 wt.
If it is contained excessively in excess of 10%, coarse alumina-based inclusions are formed and the toughness deteriorates. Therefore, the Al content is set to 0.01 to 0.05 wt%.
【0023】Cuは重要な元素であり、圧延冷却後の時
効析出強化作用を活用することにより、低炭素当量化、
低炭素化を可能にし、さらに、溶接性の向上、溶接部の
溶接熱影響部の靭性(CTOD特性)を向上させること
を可能にする効果があり、含有量が0.6wt%未満で
は析出硬化作用を活用することができず、また、2.0
wt%を越えて含有させると靭性を低下させる。よっ
て、Cu含有量は0.6〜2.0wt%とする。Cu is an important element, and by utilizing the aging precipitation strengthening action after rolling and cooling, a low carbon equivalent,
It has the effect of making it possible to lower the carbon content, improve weldability, and improve the toughness (CTOD property) of the weld heat affected zone of the weld zone. If the content is less than 0.6 wt%, precipitation hardening occurs. The action cannot be utilized, and it is 2.0
If it is contained in excess of wt%, the toughness is lowered. Therefore, the Cu content is set to 0.6 to 2.0 wt%.
【0024】NiはCu析出強化型鋼板において、Cu
含有に起因する熱間圧延時の割れを防止する効果を有す
る元素であり、含有量が0.3wt%未満ではこのよう
な効果を期待することができず、また、靭性を向上させ
る効果があるが、3.5wt%を越えて含有させると効
果は飽和してしまい、それ以上の含有は無駄である。よ
って、Ni含有量は0.3〜3.5wt%とする。Ni is Cu in the Cu precipitation strengthened steel plate.
It is an element that has the effect of preventing cracking during hot rolling due to its content. If the content is less than 0.3 wt%, such an effect cannot be expected, and it has the effect of improving toughness. However, if the content exceeds 3.5 wt%, the effect is saturated, and the content higher than that is useless. Therefore, the Ni content is set to 0.3 to 3.5 wt%.
【0025】NbはCと共に重要な元素であり、一般に
は溶接部の溶接熱影響部の靭性を著しく害するので、極
力少量の含有量に制限する必要があるといわれており、
特に、良好な溶接熱影響部の靭性(CTOD特性)を得
るために、Nb<0.02wt%とする必要があると言
われているが、しかし、C≦0.06wt%では、Nb
≧0.02wt%とする方が、鋼板の組織が微細なフェ
ライト主体の組織となり、高強度高靭性が図れると共
に、溶接継手部の溶接熱影響部の靭性(CTOD特性)
も良好となり、また、Nbを0.05wt%を越えて多
量に含有させると溶接継部の靭性が劣化する。よって、
Nb含有量は0.02〜0.05wt%とする。Nb, together with C, is an important element and generally significantly impairs the toughness of the weld heat affected zone of the weld zone, so it is said that it is necessary to limit the content to a minimum amount,
In particular, it is said that Nb <0.02 wt% is required in order to obtain good toughness (CTOD property) of the weld heat affected zone, but when C ≦ 0.06 wt%, Nb is
When ≧ 0.02 wt%, the structure of the steel sheet becomes a structure mainly composed of fine ferrite, and high strength and high toughness can be achieved, and the toughness of the weld heat affected zone of the welded joint (CTOD characteristics)
Also becomes good, and if a large amount of Nb is contained in excess of 0.05 wt%, the toughness of the welded joint deteriorates. Therefore,
The Nb content is 0.02 to 0.05 wt%.
【0026】Tiは溶接熱影響部の靭性(CTOD特
性)向上に効果のある重要な元素であり、鋼板中に析出
したTiNが溶接により加熱された時のオーステナイト
粒の粗大化を防止し、フェライト変態を促進するが、含
有量が0.005wt%未満ではこのような効果は期待
できず、また、0.020wt%を越えて含有させると
靭性が劣化する。よって、Ti含有量は0.005〜0.
020wt%とする。Ti is an important element effective in improving the toughness (CTOD characteristic) of the heat-affected zone of welding, and prevents TiN precipitated in the steel sheet from coarsening austenite grains when heated by welding, and Although the transformation is promoted, if the content is less than 0.005 wt%, such an effect cannot be expected, and if it exceeds 0.020 wt%, the toughness deteriorates. Therefore, the Ti content is 0.005 to 0.
It is set to 020 wt%.
【0027】NはTiとTiNを生成し、溶接熱影響部
の靭性(CTOD特性)を改善する効果を有する元素で
あり、含有量が0.003未満ではこの効果は少なく、
また、0.008wt%を越えて含有させると靭性が劣
化する。よって、N含有量は0.003〜0.008wt
%とする。N is an element which produces Ti and TiN and has an effect of improving the toughness (CTOD characteristic) of the weld heat affected zone. If the content is less than 0.003, this effect is small,
Further, if the content exceeds 0.008 wt%, the toughness deteriorates. Therefore, the N content is 0.003 to 0.008 wt.
%.
【0028】Caは破壊発生の起点となる介在物を低
減、微細化、形態制御を行うことにより、溶接部の溶接
熱影響部の靭性(CTOD特性)を向上する効果を有す
る特徴的な元素であり、特に、有害なAl2O3(アルミ
ナ)系の粗大な介在物を溶湯中に凝集浮上させる効果が
あり、アルミナ系介在物の量を低減させると共に微細に
分散させ、MnS介在物の形態制御が行われ、含有量が
0.0005wt%未満ではこのような効果は少なく、
また、0.0030wt%を越えて含有させると、Ca
とアルミナの複合した極めて粗大な介在物が生じる。よ
って、Ca含有量は0.0005〜0.0030wt%と
する。Ca is a characteristic element that has the effect of improving the toughness (CTOD characteristics) of the weld heat affected zone of the weld by reducing, refining, and controlling the morphology of inclusions that are the starting points of fracture occurrence. Yes, in particular, it has the effect of flocculating coarse Al 2 O 3 (alumina) -based inclusions in the molten metal, and reduces the amount of alumina-based inclusions and finely disperses them to form MnS inclusions. If the content is controlled and the content is less than 0.0005 wt%, such effect is small,
Also, if the content exceeds 0.0030 wt%, Ca
Coarse inclusions of alumina and alumina are formed. Therefore, the Ca content is 0.0005 to 0.0030 wt%.
【0029】Crは強度上昇に有効な元素であり、含有
量が0.01wt%未満ではこのような効果は少なく、
また、0.50wt%を越えて多量に含有させると溶接
性を阻害するようになる。よって、Cr含有量は0.0
1〜0.50wt%とする。Cr is an element effective in increasing strength, and if the content is less than 0.01 wt%, such an effect is small,
Also, if a large amount is added in excess of 0.50 wt%, the weldability will be impaired. Therefore, the Cr content is 0.0
1 to 0.50 wt%.
【0030】Moは強度上昇に有効な元素であり、含有
量が0.01wt%未満ではこのような効果は少なく、
また、0.50wt%を越えて多量に含有させると溶接
性を阻害するようになる。よって、Mo含有量は0.0
1〜0.50wt%とする。Mo is an element effective for increasing strength, and if the content is less than 0.01 wt%, such an effect is small,
Also, if a large amount is added in excess of 0.50 wt%, the weldability will be impaired. Therefore, the Mo content is 0.0
1 to 0.50 wt%.
【0031】Vは強度上昇に有効な元素であり、含有量
が0.005wt%未満ではこのような効果は少なく、
また、0.10wt%を越えて多量に含有させると溶接
性および靭性を阻害するようになる。よって、V含有量
は0.005〜0.10wt%とする。V is an element effective for increasing strength, and if the content is less than 0.005 wt%, such an effect is small,
Further, if it is contained in a large amount exceeding 0.10 wt%, the weldability and toughness will be impaired. Therefore, the V content is set to 0.005 to 0.10 wt%.
【0032】REMはMnSの介在物形態制御に効果が
あり、Caのようなアルミナ系介在物の量を低減させる
効果は少ないので、付加的に含有させることができ、含
有量が0.005wt%未満ではこの効果は少なく、ま
た、0.050wt%を越えて多量に含有させると有害
な粗大介在物を生成させる。よって、REM含有量は
0.005〜0.050wt%とする。REM has an effect of controlling the morphology of inclusions of MnS and has a small effect of reducing the amount of alumina-based inclusions such as Ca, so that it can be added additionally, and the content is 0.005 wt%. If it is less than the above, this effect is small, and if it is contained in a large amount exceeding 0.050 wt%, harmful coarse inclusions are formed. Therefore, the REM content is 0.005 to 0.050 wt%.
【0033】中心偏析部は成分元素が濃縮されるために
その部分が硬化し、脆化するため破壊発生の起点とな
り、特に、CとPが偏析し易く、Cが0.06wt%を
越えると島状マルテンサイト(M−A)が増大する。従
って、中心偏析部においてはC含有量は0.06wt%
以下とする必要がある。また、Pは粒界偏析により靭性
を劣化させるため、中心偏析部においてP含有量は0.
015wt%以下とする必要がある。The central segregated portion becomes a starting point of fracture occurrence due to hardening of the constituent element due to concentration of constituent elements and embrittlement. Particularly, C and P are easily segregated, and when C exceeds 0.06 wt%. Island martensite (MA) increases. Therefore, the C content in the center segregation portion is 0.06 wt%
It is necessary to: Further, since P deteriorates the toughness due to the segregation of grain boundaries, the P content in the center segregated portion is 0.
It is necessary to make it 015 wt% or less.
【0034】この中心偏析部の成分は分析する領域によ
って大きく異なり、EPMAおよびCMAによる微小領
域における分析では高濃度の分析結果となる。従って、
この鋼板の中心偏析部では、先ず、マクロエッチした後
最も偏析している部分、(板厚/50)mm厚×10m
m×10mmにおける平均化学分析値が、鋼板の成分に
かかわらず、C含有量≦0.06wt%、P含有量≦0.
015wt%とする中心偏析レベルの鋼板とする。The components of the central segregation portion greatly differ depending on the area to be analyzed, and the analysis in a minute area by EPMA and CMA gives a high-concentration analysis result. Therefore,
In the center segregation part of this steel plate, first, the most segregated part after macro etching, (plate thickness / 50) mm thickness × 10 m
The average chemical analysis values in m × 10 mm are C content ≦ 0.06 wt% and P content ≦ 0.0, regardless of the components of the steel sheet.
The steel plate has a center segregation level of 015 wt%.
【0035】介在物は破壊発生の起点となるものであ
り、破壊発生の起点となる介在物は、Al2O3(アルミ
ナ)を主成分とする塊状の介在物が連なったようなB系
介在物が多く、MnSの伸長したA系介在物から破壊が
発生する場合もある。The inclusions are the starting points of the fracture occurrence, and the inclusions of the fracture initiation point are B type inclusions in which massive inclusions containing Al 2 O 3 (alumina) as a main component are connected. There are many things, and fracture may occur from the A type inclusions in which MnS is elongated.
【0036】特に、アルミナ系介在物は溶接による熱と
応力により界面が剥離し、破壊の起点となる。断面で観
察される厚さ100μm以上、かつ、長さ50μm以上
の介在物から破壊が発生することが多い。よって、断面
で観察される厚さ10μm以上、かつ、長さ50μm以
上の介在物の個数を10mm2内に1個以下となるよう
にする。In particular, alumina-based inclusions become the starting point of fracture due to the peeling of the interface due to heat and stress caused by welding. Breakage often occurs from inclusions having a thickness of 100 μm or more and a length of 50 μm or more observed in a cross section. Therefore, the number of inclusions having a thickness of 10 μm or more and a length of 50 μm or more observed in the cross section is set to be 1 or less within 10 mm 2 .
【0037】鋼板の組織も溶接後の靭性に影響を与え
る。即ち、溶接熱影響部の靭性の最も劣化する部分は、
溶接線(Fusion Line)近傍の1200℃よ
りも高温に加熱されたオーステナイト粗粒域の部分(C
oarse Grain HAZ)であるといわれてい
る。The structure of the steel sheet also affects the toughness after welding. That is, the part where the toughness of the weld heat affected zone is most deteriorated is
A portion of the austenite coarse grain region (C) heated to a temperature higher than 1200 ° C. in the vicinity of the welding line (Fusion Line)
It is said that this is the eastern part of the city.
【0038】しかし、実際の溶接部の溶接熱影響部試験
(CTOD試験)における破壊は、必ずしも粗粒域の部
分を起点として発生しているのではなく、結局、120
0℃よりも低い温度に加熱される領域についても、良好
な靭性を保持させておく必要があり、これは、鋼板の組
織およびNb炭窒化物の分散状態が影響する。However, the fracture in the welding heat-affected zone test (CTOD test) of the actual weld does not always occur from the coarse grain region as a starting point, and eventually 120
It is necessary to maintain good toughness even in the region heated to a temperature lower than 0 ° C. This is affected by the structure of the steel sheet and the dispersed state of Nb carbonitride.
【0039】そして、Nb炭窒化物を微細に分散させる
ためには、鋼板製造時に圧延後加速冷却、または、DQ
のような比較的速い冷却を行う必要があり、その時の組
織は微細なアシキュラーフェライト、ポリゴナルフェラ
イトの1種または2種を含有している組織となる。In order to finely disperse the Nb carbonitride, accelerated cooling after rolling or DQ is performed at the time of manufacturing the steel sheet.
It is necessary to perform relatively fast cooling as described above, and the structure at that time is a structure containing one or two of fine acicular ferrite and polygonal ferrite.
【0040】また、2相域に加熱される部分の靭性を向
上させるには、鋼板の組織はベイナイト組織やマルテン
サイト組織ではなく、フェライト主体の組織とし、島状
マルテンサイト(M−A)を微細に分散させるようにす
るのがよい。そのためには、粒径20μm以下のアシキ
ュラーフェライトまたはポリゴナルフェライトの1種ま
たは2種を合計で40%以上含有した組織とする必要が
ある。そして、この組織は、鋼板を高強度高靭性化する
組織でもある。Further, in order to improve the toughness of the portion heated to the two-phase region, the structure of the steel sheet is not a bainite structure or a martensite structure but a structure mainly composed of ferrite and island martensite (MA) is used. It is better to disperse finely. For that purpose, it is necessary to have a structure containing one or two kinds of acicular ferrite or polygonal ferrite having a particle diameter of 20 μm or less in total of 40% or more. And this structure is also a structure which makes a steel plate have high strength and high toughness.
【0041】[0041]
【実 施 例】本発明に係る高強度高靭性鋼板の実施例
を比較例と共に説明する。[Examples] Examples of high strength and high toughness steel sheets according to the present invention will be described together with comparative examples.
【0042】[0042]
【実 施 例】表1に示す含有成分および成分割合の鋼を
常法により溶製後、連続鋳造を行い、製造された鋳片を
加熱・圧延・冷却後、Cu析出強化処理を行って、供試
鋼板を作製した。[Examples] Steels having the components and component ratios shown in Table 1 were melted by a conventional method, continuous casting was performed, and the produced slabs were heated, rolled and cooled, and then subjected to Cu precipitation strengthening treatment, A test steel plate was produced.
【0043】作製された鋼板から組織分率、中心偏析部
の成分分析、鋼板断面の介在物観察および引張試験、シ
ャルピー衝撃試験を行い、さらに、K開先における溶接
後、垂直ビード側の溶接線近傍HAZ部にノッチを入
れ、シャルピー衝撃試験および板厚中央部30mm厚に
おける溶接熱影響部の試験を行った。From the produced steel sheet, the structural fraction, the component analysis of the center segregation portion, the observation of inclusions in the steel sheet cross section and the tensile test and the Charpy impact test were conducted, and further, after welding in the K groove, the welding line on the vertical bead side. A notch was formed in the HAZ portion in the vicinity, and a Charpy impact test and a test of the weld heat affected zone at a thickness center portion of 30 mm were performed.
【0044】結果を表2および表3に示す。本発明に係
る高強度高靭性鋼板は、高強度、高靭性、かつ、溶接継
手部には優れたシャルピー衝撃特性および溶接熱影響部
の靭性(CTOD特性)を有していることが分かる。The results are shown in Tables 2 and 3. It can be seen that the high-strength, high-toughness steel sheet according to the present invention has high strength, high toughness, and excellent Charpy impact characteristics and weld heat-affected zone toughness (CTOD characteristics) in the weld joint.
【0045】即ち、本発明に係る高強度高靭性鋼板のN
o.1、No.5、No.6、No.8、No.10は何れ
も降伏強度460MPa以上、−80℃における吸収エ
ネルギー(vE)が100J以上、遷移温度(vTr
s)が−80℃以下であり、溶接継手部の靭性が−60
℃における吸収エネルギー100J以上、−30℃にお
けるCTOD値0.25mm以上と優れた特性を示して
いる。That is, N of the high strength and high toughness steel sheet according to the present invention
No. 1, No. 5, No. 6, No. 8, and No. 10 all have a yield strength of 460 MPa or more, an absorbed energy (vE) at −80 ° C. of 100 J or more, and a transition temperature (vTr).
s) is -80 ° C or lower, and the toughness of the welded joint is -60.
It shows excellent characteristics with absorbed energy of 100 J or more at ℃ and CTOD value of 0.25 mm or more at -30 ℃.
【0046】これに対して、比較例No.11はC含有
量が高く、Nb含有量が低いため鋼板の靭性と溶接継手
部の靭性が低い、比較例No.12とNo.14はCaが
含有されていないため、介在物の個数が多く、溶接継手
部の靭性、CTOD値が低い。On the other hand, Comparative Example No. 11 has a high C content and a low Nb content, so that the toughness of the steel plate and the toughness of the welded joint are low. In Comparative Examples No. 12 and No. 14, Ca is Since it is not contained, the number of inclusions is large, and the toughness and CTOD value of the welded joint are low.
【0047】比較例No.13はCu含有量が低いため
鋼板の強度が低い。比較例No.15はTiが含有され
ていないため、鋼板の靭性と溶接継手部の靭性が低い。
比較例No.16はP含有量が多く、中心偏析している
ため溶接継手部CTOD値が低い。In Comparative Example No. 13, since the Cu content is low, the strength of the steel sheet is low. Since Comparative Example No. 15 does not contain Ti, the toughness of the steel sheet and the toughness of the welded joint are low.
Comparative Example No. 16 has a large P content and is segregated at the center, so the CTOD value of the welded joint is low.
【0048】比較例No.2、No.3およびNo.7は
鋼板の組織が微細なフェライト主体の組織なっていない
しため、鋼板の靭性が低い。比較例No.4、No.9は
中心偏析部にCおよびPが濃縮されているため、溶接継
手部のCTOD値が低いのである。In Comparative Examples No. 2, No. 3 and No. 7, the steel sheet does not have a fine ferrite-based structure, so that the steel sheet has low toughness. In Comparative Examples No. 4 and No. 9, C and P are concentrated in the central segregation portion, so that the CTOD value of the welded joint portion is low.
【0049】[0049]
【表1】 [Table 1]
【表2】 [Table 2]
【0051】[0051]
【表3】 [Table 3]
【0052】[0052]
【発明の効果】以上説明したように、本発明に係る高強
度高靭性鋼板は上記の構成であるから、降伏強さ460
MPa以上の高強度と遷移温度(vTrs)−80℃以
下の高靭性を有すると共に、溶接継手部においても優れ
たシャルピー衝撃特性と優れた溶接熱影響部の靭性(C
TOD特性)を得ることが可能となり、産業上の効果は
極めて大きいものである。As described above, since the high-strength and high-toughness steel sheet according to the present invention has the above constitution, the yield strength 460 is
It has high strength of MPa or more and high toughness of transition temperature (vTrs) -80 ° C. or less, and also has excellent Charpy impact characteristics in the welded joint and excellent toughness of the weld heat affected zone (C
It becomes possible to obtain TOD characteristics), and the industrial effect is extremely large.
Claims (2)
01〜0.50wt%、 Mn 0.5〜2.0wt%、P ≦ 0.015wt
%、 S ≦ 0.005wt%、Al 0.01〜0.05w
t%、 Cu 0.6〜2.0wt%、Ni 0.3〜3.5wt
%、 Nb 0.02〜0.05wt%、Ti 0.005〜0.
02wt%、 N 0.003〜0.008wt%、Ca 0.0005
〜0.0030wt% を含有し、残部Feおよび不可避不純物からなり、か
つ、鋼板の中心偏析部(板厚/50)mm厚×10mm
×10mmの平均化学分析値が C ≦ 0.06wt%、P ≦ 0.015wt% であり、断面で観察される厚さ10μm以上、長さ50
μm以上の介在物が10mm2内に1個以下、鋼板の組
織が粒径20μm以下のアシキュラーフェライト、また
は、ポリゴナルフェライトを合計40%以上含有されて
いることを特徴とする高強度高靭性鋼板。1. C 0.01 to 0.06 wt%, Si 0.0.
01 to 0.50 wt%, Mn 0.5 to 2.0 wt%, P ≤ 0.015 wt%
%, S ≤ 0.005 wt%, Al 0.01 to 0.05 w
t%, Cu 0.6 to 2.0 wt%, Ni 0.3 to 3.5 wt
%, Nb 0.02 to 0.05 wt%, Ti 0.005 to 0.
02 wt%, N 0.003 to 0.008 wt%, Ca 0.0005
To 0.0003 wt%, the balance Fe and unavoidable impurities, and the center segregated portion of the steel sheet (sheet thickness / 50) mm thickness x 10 mm
The average chemical analysis values of × 10 mm are C ≦ 0.06 wt% and P ≦ 0.015 wt%, and the thickness observed on the cross section is 10 μm or more and the length is 50 μm.
High strength and high toughness characterized by containing 1 or less inclusions of 10 μm or more in 10 mm 2 and acicular ferrite having a grain size of 20 μm or less or polygonal ferrite in a total content of 40% or more. steel sheet.
01〜0.50wt%、 Mn 0.5〜2.0wt%、P ≦ 0.015wt
%、 S ≦ 0.005wt%、Al 0.01〜0.05w
t%、 Cu 0.6〜2.0wt%、Ni 0.3〜3.5wt
%、 Nb 0.02〜0.05wt%、Ti 0.005〜0.
02wt%、 N 0.003〜0.008wt%、Ca 0.0005
〜0.0030wt% を含有し、さらに、 Cr 0.01〜0.50wt%、Mo 0.01〜0.5
0wt%、 V 0.005〜0.10wt% の内から選んだ1種または2種以上を含有し、かつ、 REM 0.005〜0.050wt% を含有し、残部Feおよび不可避不純物からなり、か
つ、鋼板の中心偏析部(板厚/50)mm厚×10mm
×10mmの平均化学分析値が C ≦ 0.06wt%、P ≦ 0.015wt% であり、断面で観察される厚さ10μm以上、長さ50
μm以上の介在物が10mm2内に1個以下、鋼板の組
織が粒径20μm以下のアシキュラーフェライト、また
は、ポリゴナルフェライトを合計40%以上含有されて
いることを特徴とする高強度高靭性鋼板。2. C 0.01 to 0.06 wt%, Si 0.04.
01 to 0.50 wt%, Mn 0.5 to 2.0 wt%, P ≤ 0.015 wt%
%, S ≤ 0.005 wt%, Al 0.01 to 0.05 w
t%, Cu 0.6 to 2.0 wt%, Ni 0.3 to 3.5 wt
%, Nb 0.02 to 0.05 wt%, Ti 0.005 to 0.
02 wt%, N 0.003 to 0.008 wt%, Ca 0.0005
.About.0.0030 wt%, Cr 0.01-0.50 wt%, Mo 0.01-0.5
0 wt%, V 0.005 to 0.10 wt% selected from 1 or 2 or more, and REM 0.005 to 0.050 wt%, the balance Fe and inevitable impurities, And the center segregated part of the steel plate (plate thickness / 50) mm thickness x 10 mm
The average chemical analysis values of × 10 mm are C ≦ 0.06 wt% and P ≦ 0.015 wt%, and the thickness observed on the cross section is 10 μm or more and the length is 50 μm.
High strength and high toughness characterized by containing 1 or less inclusions of 10 μm or more in 10 mm 2 and acicular ferrite having a grain size of 20 μm or less or polygonal ferrite in a total content of 40% or more. steel sheet.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP4858993A JP2688312B2 (en) | 1993-02-15 | 1993-02-15 | High strength and high toughness steel plate |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP4858993A JP2688312B2 (en) | 1993-02-15 | 1993-02-15 | High strength and high toughness steel plate |
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JPH06240406A JPH06240406A (en) | 1994-08-30 |
JP2688312B2 true JP2688312B2 (en) | 1997-12-10 |
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JP4858993A Expired - Lifetime JP2688312B2 (en) | 1993-02-15 | 1993-02-15 | High strength and high toughness steel plate |
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Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
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US5964964A (en) * | 1996-02-13 | 1999-10-12 | Nippon Steel Corporation | Welded joint of high fatigue strength |
GB0005023D0 (en) * | 2000-03-03 | 2000-04-26 | British Steel Ltd | Steel composition and microstructure |
JP5459166B2 (en) * | 2010-09-28 | 2014-04-02 | 新日鐵住金株式会社 | Steel plate for ice sea structure |
EP2894235B1 (en) * | 2012-09-06 | 2019-01-09 | JFE Steel Corporation | Thick-walled, high tensile strength steel with excellent ctod characteristics of the weld heat-affected zone, and manufacturing method thereof |
CN103667905B (en) * | 2013-12-04 | 2015-12-02 | 武汉钢铁(集团)公司 | The superfine crystal particle structural steel that plasticity and toughness are excellent and production method |
CN112795849B (en) * | 2020-11-20 | 2022-07-12 | 唐山钢铁集团有限责任公司 | 1300Mpa high-toughness hot-dip galvanized steel plate and production method thereof |
-
1993
- 1993-02-15 JP JP4858993A patent/JP2688312B2/en not_active Expired - Lifetime
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JPH06240406A (en) | 1994-08-30 |
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