JP2003193190A - Galvanized high strength steel sheet having excellent weldability, hole expansibility and corrosion resistance and production method therefor - Google Patents
Galvanized high strength steel sheet having excellent weldability, hole expansibility and corrosion resistance and production method thereforInfo
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- JP2003193190A JP2003193190A JP2001399396A JP2001399396A JP2003193190A JP 2003193190 A JP2003193190 A JP 2003193190A JP 2001399396 A JP2001399396 A JP 2001399396A JP 2001399396 A JP2001399396 A JP 2001399396A JP 2003193190 A JP2003193190 A JP 2003193190A
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- steel sheet
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Abstract
Description
【0001】[0001]
【発明の属する技術分野】本発明は、建材、家電製品、
自動車などに適する溶接性、穴拡げ性および耐食性に優
れた溶融亜鉛めっき高強度鋼板および溶融合金化亜鉛め
っき鋼板とその製造方法に関する。TECHNICAL FIELD The present invention relates to building materials, home electric appliances,
TECHNICAL FIELD The present invention relates to a hot-dip galvanized high-strength steel sheet and a hot-dip galvanized steel sheet having excellent weldability, hole expandability, and corrosion resistance suitable for automobiles, and a method for producing the same.
【0002】[0002]
【従来の技術】近年、特に自動車車体において燃費向上
や耐久性向上の観点を目的とした加工性の良い高強度鋼
板の需要が高まっている。加えて、衝突安全性やキャビ
ンスペースの拡大のニーズから引張り強度にして800MPa
級クラス以上の鋼板が、一部レインフォースなどの部材
に使用されつつある。これら部材の耐久性には、溶接部
や加工部分の疲労耐久性や耐食性が挙げられる。このよ
うな高強度材を用いて部材を組みあげる時には、延性、
曲げ性、穴拡げ性などが、引張り強度で590MPa程
度までの高強度鋼板以上に大きな問題となるため、これ
らに対する対策が必要となる。2. Description of the Related Art In recent years, there has been an increasing demand for high-strength steel sheets with good workability, especially for the purpose of improving fuel efficiency and durability in automobile bodies. In addition, the tensile strength is 800 MPa because of the needs of collision safety and expansion of cabin space.
Steel sheets of higher grade or higher are being used in parts such as reinforcements. The durability of these members includes fatigue durability and corrosion resistance of welded parts and processed parts. When assembling members using such high strength materials, ductility,
Bendability, hole expandability, and the like are more serious problems than high-strength steel sheets having a tensile strength of up to about 590 MPa, and countermeasures against them are necessary.
【0003】各特性に対して、以下のような対策が各々
講じられている。たとえば、穴拡げ性については、CAMP
-ISIJ vol.13 (2000) p.395にあるように、主相をベ
イナイトとして穴拡げ性を向上させ、さらには張り出し
性成型性についても、第2相に残留オーステナイトを生
成させることで現行の残留オーステナイト鋼並の張り出
し性を示すことが開示されている。さらには、Ms温度
以下でオーステンパ処理をすることで体積率2〜3%の
残留オーステナイトを生成させると、引張り強度×穴拡
率が最大となることも示されている。しかし、800 MP
aを超えて顕在化する溶接性および溶接熱影響部での軟
化挙動については考慮されていない。The following measures are taken for each characteristic. For example, for hole expandability, CAMP
-ISIJ vol.13 (2000) As described in p.395, bainite is used as the main phase to improve the hole expansibility, and the overhanging formability is also improved by forming retained austenite in the second phase. It is disclosed that it exhibits the same bulging property as that of retained austenitic steel. Furthermore, it is also shown that when austenite treatment with Ms temperature or less is performed to generate retained austenite with a volume ratio of 2 to 3%, the tensile strength × hole expansion ratio becomes maximum. But 800 MP
The weldability and the softening behavior in the heat-affected zone which are actualized beyond a are not considered.
【0004】また、溶接性については、溶接熱影響部に
おける軟化挙動(HAZ 軟化挙動)が問題視されるケース
が多い。これに対して、例えば特開2000-87175にあるよ
うにNbおよびMoの炭化物(Nb、Mo)Cの析出により
HAZ 軟化挙動を抑制することが示されている。しかし、
この技術は、疲労強度に関して考慮されているものの穴
拡げ性等の加工性について十分な考慮はない。また、HA
Z 軟化挙動を抑制の効果も強度レベルが低く、800 MP
a以上の極めて高強度な材料における溶接性や加工性に
ついて十分とはいえない。特に、引張り強度が800 MP
a 以上になると、溶接自体が困難になり、980MPa以上で
更に顕著となる。このため、スポット溶接等の従来の溶
接方法に加えてレーザー溶接なども一部適用される例も
ある。しかし、高強度故、特に溶接部および熱影響部で
の材質変動が590MPa クラス以上の高強度材に比べ
極めて顕著となる。Regarding the weldability, the softening behavior (HAZ softening behavior) in the heat-affected zone of welding is often regarded as a problem. On the other hand, for example, as disclosed in Japanese Unexamined Patent Publication No. 2000-87175, by precipitation of Nb and Mo carbides (Nb, Mo) C,
It has been shown to suppress HAZ softening behavior. But,
Although this technique considers fatigue strength, it does not sufficiently consider workability such as hole expandability. Also HA
The effect of suppressing the Z softening behavior is low at 800MP.
It cannot be said that the weldability and workability of extremely high strength materials of a or higher are sufficient. Especially, the tensile strength is 800MP
If it is a or more, welding itself becomes difficult, and it becomes more remarkable at 980 MPa or more. Therefore, in some cases, in addition to conventional welding methods such as spot welding, laser welding and the like are partially applied. However, because of the high strength, the material variation in the welded part and the heat-affected zone is extremely remarkable as compared with the high-strength material of 590 MPa class or higher.
【0005】また、高強度材の高延性化を図るために、
複合組織化を積極的に活用することが一般的である。し
かし、第2相にマルテンサイトや残留オーステナイトを
活用した場合に、穴拡げ性が著しく低下してしまうとい
う問題がある(例えば、CAMP-ISIJ, vol.13(2000),p.3
91)。また、本文献中には、主相をフェライト、第2相
をマルテンサイトととし、両者の硬度差を減少させるこ
とで穴拡げ率が向上することが開示されているが、穴拡
げ率で70%未満と、著しく改善されているわけではな
い。さらに、これらの鋼板には、Siなどが添加された
り、溶融亜鉛めっき工程での材質の確保や、めっき性や
その後の耐食性の考慮が十分でない。In order to increase the ductility of high strength materials,
It is common to actively utilize complex organization. However, when martensite or retained austenite is used for the second phase, there is a problem that the hole expandability is significantly reduced (for example, CAMP-ISIJ, vol.13 (2000), p.3).
91). Further, this document discloses that the main phase is ferrite and the second phase is martensite, and the hole expansion ratio is improved by reducing the difference in hardness between the two, but the hole expansion ratio is 70%. If it is less than%, it is not a significant improvement. Further, Si or the like is added to these steel sheets, the material is not secured in the hot dip galvanizing process, and the plating properties and the subsequent corrosion resistance are not sufficiently taken into consideration.
【0006】[0006]
【発明が解決しようとする課題】本発明は、前述のよう
な従来技術の問題点を解決し、引張り強度が800 MPa
以上の高強度鋼板の溶接性および穴拡げ性を改善し、溶
融亜鉛めっきおよび溶融合金化亜鉛めっきを可能とした
耐食性に優れた高強度鋼板およびその製造方法を提供す
ることを目的とする。SUMMARY OF THE INVENTION The present invention solves the problems of the prior art as described above, and has a tensile strength of 800 MPa.
It is an object of the present invention to provide a high-strength steel sheet having improved corrosion resistance and improved weldability and hole expandability of the above high-strength steel sheet, which enables hot-dip galvanizing and hot-dip galvannealing, and a method for producing the same.
【0007】[0007]
【課題を解決するための手段】本発明者らは、種々検討
を行った結果、引張り強度を800 MPa以上の領域で、
溶接性、穴拡げ性を同時に改善する手法として、ミクロ
組織およびを成分範囲や(A)式による限定を行うこと
で、800 MPa以上の高強度を保ちつつ溶接熱影響部の
軟化挙動を抑制して溶接部の疲労耐久性を向上させ、さ
らには、穴拡げ率:(穴拡げ試験前の穴の内径/穴拡げ
試験前の穴径−1)×100が70%以上の穴拡げ性を
確保できることを見出した。さらに、式(B)または
(C)を満たすことでめっき性を改善し、耐食性の向上
を図ることが可能なことを見出した。Means for Solving the Problems As a result of various studies, the present inventors have found that the tensile strength is 800 MPa or more.
As a method of simultaneously improving weldability and hole expandability, by limiting the microstructure and the composition range and formula (A), the softening behavior of the weld heat affected zone is suppressed while maintaining a high strength of 800 MPa or more. Improves the fatigue durability of the welded part, and further secures a hole expandability of 70% or more if the hole expansion ratio: (hole inner diameter before hole expansion test / hole diameter before hole expansion test-1) x 100 I found that I could do it. Further, it has been found that it is possible to improve the plating property and the corrosion resistance by satisfying the formula (B) or (C).
【0008】本発明は、上記知見に基づいて完成された
もので、その要旨とするところは以下の通りである。
(1) 質量%で、C :0.01〜0.20%、S
i:1.5%以下、Mn:0.01〜3%、P:0.0
010〜0.1%、S:0.0010〜0.05%、A
l:0.005〜4%を含有し、さらに、Mo:0.0
1〜5.0%、Nb:0.001〜1.0%の1種また
は2種を下記(A)および(B)式を同時に満たす範囲
で含有し、残部をFeおよび不可避的不純物とし、ミクロ
組織が、ベイナイトまたはベイニティックフェライトと
して面積率で70%以上含有し、引張強度が800MPa以上
であることを特徴とする溶接性、穴拡げ性および耐食性
に優れた溶融亜鉛めっき高強度鋼板。
3.0Nb+2.5Mo+Mn−5C0.5 > 0 ・・・(A)
Al+15.0Si2 +1.5Si-1.8 < 0 ・・・(B)The present invention has been completed based on the above findings, and the gist thereof is as follows. (1)% by mass, C: 0.01 to 0.20%, S
i: 1.5% or less, Mn: 0.01 to 3%, P: 0.0
010-0.1%, S: 0.0010-0.05%, A
1: 0.005 to 4%, and Mo: 0.0
1 to 5.0%, Nb: 0.001 to 1.0% of one or two are contained in a range that simultaneously satisfies the following formulas (A) and (B), and the balance is Fe and inevitable impurities, A hot-dip galvanized high-strength steel sheet excellent in weldability, hole expansibility and corrosion resistance, characterized in that the microstructure contains bainite or bainitic ferrite in an area ratio of 70% or more and a tensile strength of 800 MPa or more. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 ・ ・ ・ (A) Al + 15.0Si 2 + 1.5Si-1.8 <0 ・ ・ ・ (B)
【0009】(2) さらに、質量%で、Cr:0.0
1〜5%、Ni:0.01〜5%、Cu:0.01〜5
%、の1種または2種以上を含有することを特徴とし、
さらに式(A)および(C)を満たす(1)に記載(た
だし本項では式(B)を満たす必要はない)の溶接性、
穴拡げ性および耐食性に優れた溶融亜鉛めっき高強度鋼
板。
3.0Nb+2.5Mo+Mn−5C0.5 > 0 ・・・(A)
Al+15.0Si2 +1.5Si +0.5Cr −(30Ni +10Cu) −1.8 < 0 ・・・(C)(2) Further, in mass%, Cr: 0.0
1-5%, Ni: 0.01-5%, Cu: 0.01-5
%, Containing one or more of
Furthermore, the weldability described in (1) that satisfies the formulas (A) and (C) (however, it is not necessary to satisfy the formula (B) in this section),
Hot-dip galvanized high-strength steel sheet with excellent hole expandability and corrosion resistance. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 ・ ・ ・ (A) Al + 15.0Si 2 + 1.5Si + 0.5Cr − (30Ni + 10Cu) −1.8 <0 ・ ・ ・ (C)
【0010】(3) さらに、質量%で、Co:0.0
1〜5%、W :0.01〜5%の1種または2種以上
を含有することを特徴とする(1)または(2)に記載
の溶接性、穴拡げ性および耐食性に優れた溶融亜鉛めっ
き高強度鋼板。(3) Further, in mass%, Co: 0.0
1 to 5%, W: 0.01 to 5% of 1 type or 2 types or more are contained, The meltability excellent in the weldability, the hole expandability, and the corrosion resistance as described in (1) or (2). Galvanized high strength steel plate.
【0011】(4) さらに、質量%で、Zr、Hf、
Ta、Ti、Vの1種または2種以上を合計で0.00
1〜1%含有することを特徴とする(1)乃至(3)に
記載の溶接性、穴拡げ性および耐食性に優れた溶融亜鉛
めっき高強度鋼板。(4) Further, in% by mass, Zr, Hf,
One or two or more of Ta, Ti, and V is 0.00 in total.
The hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance according to (1) to (3), which is characterized by containing 1 to 1%.
【0012】(5) さらに、質量%で、B:0.00
01〜0.1%を含有することを特徴とする(1)乃至
(4)に記載の溶接性、穴拡げ性および耐食性に優れた
溶融亜鉛めっき高強度鋼板。(5) Further, in mass%, B: 0.00
The hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance according to (1) to (4), which contains 0.1 to 0.1%.
【0013】(6) さらに、質量%で、Ca、Y、Re
m の1種または2種以上を合計で0.0001〜0.5
%含有することを特徴とする(1)乃至(5)に記載の
溶接性、穴拡げ性および耐食性に優れた溶融亜鉛めっき
高強度鋼板。(6) Furthermore, in% by mass, Ca, Y, Re
One or more of m is 0.0001 to 0.5 in total
%, The hot dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance according to (1) to (5).
【0014】(7) (1)乃至(6)に記載の成分か
らなる鋳造スラブを直接または一旦冷却した後に再度加
熱し、熱延後巻取った熱延鋼板を酸洗後冷延し、その後
昇温および焼鈍時の雰囲気が酸素濃度が50ppm 以下で
露点が−20℃以下とし、焼鈍時の最高温度が0.3×
(Ac3 −Ac1 )+Ac1 (℃)以上Ac3 +30
(℃)以下で焼鈍した後に、0.1〜100℃/秒の冷
却速度で亜鉛めっき浴温度−20℃〜亜鉛めっき浴温度
+50℃の温度域に冷却し、引き続いて同温度域でめっ
き浸漬を含めて1秒〜1000秒保持を行うことを特徴
とする溶接性、穴拡げ性および耐食性に優れた溶融亜鉛
めっき高強度鋼板の製造方法。(7) A cast slab comprising the components described in (1) to (6) is directly or once cooled and then reheated, and the hot rolled steel sheet rolled after hot rolling is pickled and cold rolled. The atmosphere during heating and annealing has an oxygen concentration of 50 ppm or less and a dew point of -20 ° C or less, and the maximum temperature during annealing is 0.3 ×
(Ac 3 −Ac 1 ) + Ac 1 (° C.) or more Ac 3 +30
After annealing at (° C.) or lower, it is cooled at a cooling rate of 0.1 to 100 ° C./sec to a temperature range of zinc plating bath temperature −20 ° C. to zinc plating bath temperature + 50 ° C., followed by plating immersion in the same temperature range. The method for producing a hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance, which is characterized by holding for 1 second to 1000 seconds.
【0015】(8) (7)に記載の製造方法におい
て、亜鉛めっき浴温度−20℃〜亜鉛めっき浴温度+5
0℃の温度域に冷却し、引き続いて同温度域でめっき浸
漬を含めて1秒〜1000秒保持後、合金化処理を43
0℃〜580℃を行うことを特徴とする溶接性、穴拡げ
性および耐食性に優れた溶融亜鉛めっき高強度鋼板の製
造方法。(8) In the manufacturing method described in (7), the zinc plating bath temperature is −20 ° C. to the zinc plating bath temperature +5.
After cooling to a temperature range of 0 ° C. and then holding for 1 second to 1000 seconds including plating immersion in the same temperature range, alloying treatment is performed at 43 ° C.
A method for producing a hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance, which is characterized by performing 0 ° C to 580 ° C.
【0016】[0016]
【発明の実施の形態】以下、本発明を詳細に説明する。
発明者らは、質量%で、C:0.01〜0.2%、S
i:1.5 %以下、Mn:0.01〜3%、P:0.00
10〜0.1%、S:0.0010〜0.05%、A
l:0.005〜4 %を含有し、残部Feおよび不可避
不純物からなる鋼板をベースに、各合金を添加した溶製
し、鋳造まま又は一旦冷却した後に再度加熱し、熱延後
巻取った熱延鋼板を酸洗後冷延し、その後焼鈍し、冷延
焼鈍板を作成した。その鋼板について、ミクロ組織観
察、鉄鋼連盟規定の穴拡げ試験、JIS に準拠した引張り
試験、鋼板をつきあわせてレーザー溶接を行い、その後
球頭張り出し試験を行って破断部位置を測定した。ま
た、各溶接継ぎ手を作成して、引張り- 引張りモードの
疲労試験を105 〜106 cyclesまで行い、母材との疲労強
度を比較することでめっき材の溶接継ぎ手の疲労特性を
比較評価した。ここで、溶接継ぎ手は、ビードオンで行
い、溶接後、試験片端面および表面を研削して溶接チャ
ンスによる継ぎ手形状のばらつき因子を極力少なくする
方法を採った。また、めっき性の試験は、外観観察して
5段階の評点をつけた。
評点5:不めっき等全くなく良好な外観。
評点4:めっき剥離が極めて少なく良好な外観。
評点3:不めっきやめっき剥離発生。
評点2:不めっきやめっき剥離多発。
評点1:めっき濡れず。BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described in detail below.
The inventors have found that, in mass%, C: 0.01 to 0.2%, S
i: 1.5% or less, Mn: 0.01 to 3%, P: 0.00
10-0.1%, S: 0.0010-0.05%, A
l: 0.005 to 4% by weight, steel sheet consisting of the balance Fe and unavoidable impurities was added to each alloy and melted, as-cast or once cooled and then heated again, and hot-rolled and wound. The hot rolled steel sheet was pickled, cold rolled, and then annealed to prepare a cold rolled annealed sheet. The steel sheet was observed for microstructure, a hole expansion test prescribed by the Iron and Steel Federation, a tensile test in accordance with JIS, laser welding was performed by bringing the steel sheets together, and then a ball head overhanging test was performed to measure the fracture position. In addition, each welded joint was created, and a fatigue test in a tensile-tensile mode was performed for 10 5 to 10 6 cycles, and the fatigue properties of the welded joint of the plated material were compared and evaluated by comparing the fatigue strength with the base metal. . Here, the welding joint was bead-on, and after welding, the end surface and the surface of the test piece were ground to reduce the variation factor of the joint shape due to the welding chance as much as possible. Further, in the plating property test, the appearance was observed and a rating of 5 levels was given. Rating 5: Good appearance without any plating. Rating 4: Very good appearance with very little plating peeling. Rating 3: Non-plating or peeling of plating occurred. Rating 2: Non-plating and frequent peeling of plating. Rating 1: The plating did not get wet.
【0017】また、めっき後の耐食性試験には、板厚の
3倍の曲率半径で板を曲げたあとで乾湿繰り返し試験を
自動車技術会の規格(JASO)のサイクル腐食試験を100
回まで行った。腐食状況は、外観および断面を光学顕微
鏡にて200 〜1000倍の20視野以上を観察し、内面への腐
食の進行度合いを観察することで5段階評価とした。評
点は以下のようである。
評点5:発錆等全くなく良好な外観。腐食の進行度合い
は、めっき相のみまたは母材への腐食深さが50μm未
満。
評点4:発錆が極めて少なく良好な外観。腐食の進行度
合いは、母材への腐食深さが50μm〜100 μm未満。
評点3:錆発生が明確に認められる。
評点2:錆多発。
評点1:錆多発、一部に膨れや穴あき等あり。For the corrosion resistance test after plating, after the plate is bent at a radius of curvature three times the plate thickness, a dry / wet repeated test is carried out by a 100% cycle corrosion test according to the Japanese Society of Automotive Engineers (JASO) standard.
Went up to times. The state of corrosion was evaluated on a 5-grade scale by observing the external appearance and the cross section of the visual field of 200 to 1000 times in 20 fields or more with an optical microscope and observing the progress of corrosion on the inner surface. The scores are as follows. Rating 5: Good appearance with no rust. As for the degree of corrosion progress, the corrosion depth of the plating phase only or the base metal is less than 50 μm. Rating 4: Very good appearance with little rusting. Regarding the degree of progress of corrosion, the corrosion depth of the base metal is 50 μm to less than 100 μm. Rating 3: Rust generation is clearly recognized. Rating 2: Many rust. Rating 1: Rust frequently occurred, some swelling and perforation.
【0018】その結果、最終的に得られるミクロ組織制
御により、800 MPa以上の引張り強度を得、溶接性、
穴拡げ性および耐食性に優れた溶融亜鉛めっき鋼板及び
溶融合金化亜鉛めっき高強度鋼板が製造可能なことを見
出した。As a result, the finally obtained microstructure control provides a tensile strength of 800 MPa or more, weldability,
It has been found that a hot-dip galvanized steel sheet and a hot-dip galvanized high-strength steel sheet having excellent hole expandability and corrosion resistance can be produced.
【0019】次に、基材鋼板の好ましいミクロ組織につ
いて述べる。800 MPa以上の引張り強度を得、溶接性
および穴拡げ性を両立させるためには、主相としてベイ
ナイトまたはベイニティックフェライトが適している。
溶接性および穴拡げ性を両立させるためには、面積率で
70%以上とする。Next, a preferable microstructure of the base steel sheet will be described. In order to obtain a tensile strength of 800 MPa or more and to achieve both weldability and hole expandability, bainite or bainitic ferrite is suitable as the main phase.
In order to achieve both weldability and hole expandability, the area ratio is 70% or more.
【0020】また、ここで言うベイナイトはラス境界に
炭化物が生成している上部ベイナイトおよびラス内に微
細炭化物が生成している下部ベイナイトの双方を含む。
また、ベイニティックフェライトは炭化物のないベイナ
イトを意味し、例えばアキュラーフェライトがその1例
である。穴拡げ性向上には、炭化物が微細分散している
下部ベイナイトもしくは炭化物の無いベイニティックフ
ェライトが主相で、面積率が97%を超えることが望ま
しい。The bainite referred to here includes both upper bainite in which carbide is formed at the lath boundary and lower bainite in which fine carbide is formed in lath.
In addition, bainitic ferrite means bainite without carbide, and for example, acicular ferrite is one example. In order to improve the hole expandability, it is desirable that the lower bainite in which carbide is finely dispersed or bainitic ferrite without carbide is the main phase and the area ratio exceeds 97%.
【0021】一方、溶接熱影響部での軟化防止が問題と
なる。これに対しては、後述するように成分を規定した
(A)式を満たすことで、引張り強度が800MPa以上の高
強度めっき材の溶接性および溶接後疲労強度を確保でき
る。On the other hand, prevention of softening in the heat affected zone of welding becomes a problem. On the other hand, by satisfying the formula (A) defining the components as described below, the weldability and the post-welding fatigue strength of the high-strength plated material having a tensile strength of 800 MPa or more can be secured.
【0022】延性確保や高強度化の観点からすると、面
積率で30%未満のフェライトを含んでも良い。一方、
オーステナイトおよび/またはマルテンサイトを含むこ
とは穴拡げ加工性や溶接熱影響部の軟化挙動の点から望
ましくないが、面積率3%未満程度であれば、顕著な特
性劣化が認められないことから、面積率で3%未満含ん
でも良い。さらに、酸化物や硫化物等の介在物を不可避
的に含んでも良い。From the standpoint of ensuring ductility and increasing strength, ferrite may be included in an area ratio of less than 30%. on the other hand,
The inclusion of austenite and / or martensite is not desirable from the viewpoint of hole expanding workability and softening behavior of the weld heat affected zone, but if the area ratio is less than 3%, no remarkable deterioration of properties is observed. The area ratio may be less than 3%. Further, inclusions such as oxides and sulfides may be inevitably included.
【0023】また、式(A)を満足しない場合には、め
っき材での引張り強度で800 MPa以上を確保できなか
ったり、溶接熱影響部分の軟化を抑制できず、溶接継ぎ
手の疲労特性が劣化してしまうだけでなく、穴拡げ性の
確保も困難となる。
3.0Nb+2.5Mo+Mn−5C0.5 > 0 ・・・(A)
また、上記の他にミクロ組織の残部組織として、炭化
物、窒化物、硫化物、酸化物の1又は2以上を面積率1
%以下で含有する場合も本発明で用いることができ、こ
れらは主相の面積率に含めた。Further, when the formula (A) is not satisfied, the tensile strength of the plated material cannot be secured to 800 MPa or more, the softening of the heat affected zone of the welding cannot be suppressed, and the fatigue characteristics of the welding joint deteriorate. Not only will it happen, but it will also be difficult to secure hole expandability. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 (A) Further, in addition to the above, as the remaining structure of the microstructure, 1 or 2 or more of carbide, nitride, sulfide, and oxide is used as the area ratio 1
Even when the content is less than or equal to%, it can be used in the present invention, and these are included in the area ratio of the main phase.
【0024】なお、上記ミクロ組織の各相、フェライト
(ベイニティックフェライト)、ベイナイト、オーステ
ナイト、マルテンサイト、界面酸化相および残部組織の
同定、存在位置の観察および面積率の測定は、ナイター
ル試薬および特開昭59−219473号公報に開示さ
れた試薬により鋼板圧延方向断面または圧延直角方向断
面を腐食して500倍〜1000倍の光学顕微鏡観察お
よび1000〜100000倍の電子顕微鏡(走査型お
よび透過型)により定量化が可能である。各20視野以
上の観察を行い、ポイントカウント法や画像解析により
各組織の面積率を求める事ができる。The phases of the above-mentioned microstructure, ferrite (bainitic ferrite), bainite, austenite, martensite, interfacial oxide phase and the remaining structure are identified, the existing positions are observed, and the area ratio is measured by using Nital reagent and The reagent disclosed in Japanese Patent Application Laid-Open No. 59-219473 corrodes the section in the steel sheet rolling direction or the section perpendicular to the rolling direction and observes it with an optical microscope at a magnification of 500 to 1000 times and an electron microscope at a magnification of 1000 to 100000 times (scanning type and transmission type). ) Can be quantified. It is possible to obtain the area ratio of each tissue by observing each of 20 or more visual fields and by the point counting method or image analysis.
【0025】次に、本発明における鋼板成分の好適な範
囲の限定理由について述べる。Cは、良好な強度−穴拡
げ性バランスを確保するための主相および第2相の率を
制御する目的で添加する元素である。素地の微細均一化
についても影響を与える。強度および各第2相の面積率
を確保するために下限を0.01質量%(以下、同じ)
とし、溶接性および穴拡げ性を保持可能な上限として
0.20%とした。好ましくは、C:0.05〜0.1
5%とすることにより良好な強度−穴拡げ性バランスが
得られる。Next, the reasons for limiting the preferred ranges of the steel sheet components in the present invention will be described. C is an element added for the purpose of controlling the ratios of the main phase and the second phase for ensuring a good strength-hole expandability balance. It also affects the fine homogenization of the substrate. The lower limit is 0.01% by mass (hereinafter the same) in order to secure the strength and the area ratio of each second phase.
Was set to 0.20% as the upper limit capable of maintaining weldability and hole expandability. Preferably, C: 0.05 to 0.1
When it is 5%, a good balance between strength and hole expandability can be obtained.
【0026】Siは、強度延性バランスを劣化させる比
較的粗大な炭化物の生成を抑制する目的で添加する元素
であるがめっき性を著しく劣化させる。このため1.5
%以下とした。一方で、極低下は製造コストの高騰を招
くことから、めっき性を大きくは悪化させない0.00
5以上の添加とすることが望ましい。また、過剰添加は
溶接性およびに悪影響を及ぼすため、上限を1.5質量
%とした。好ましくは、Si:0.05%以下とするこ
とによりさらに著しい効果が得られる。Si is an element added for the purpose of suppressing the formation of a relatively coarse carbide that deteriorates the strength-ductility balance, but it significantly deteriorates the plating property. For this reason 1.5
% Or less. On the other hand, the extremely low drop does not significantly deteriorate the plating property because it causes a rise in manufacturing cost.
It is desirable to add 5 or more. Further, excessive addition has an adverse effect on weldability and, therefore, the upper limit was made 1.5 mass%. Preferably, by setting Si: 0.05% or less, a more remarkable effect can be obtained.
【0027】Mnは、高強度化の目的で添加する。ま
た、フェライト変態を抑制して、主相をベイナイトまた
はベイニティックフェライトにするのに有効である。さ
らに、強度低下と穴拡げ性劣化の1つの原因である炭化
物析出や、パーライト生成を抑制する目的で添加する。
これらのことから、0.01質量%以上とした。一方、
過剰添加は、マルテンサイト生成を促進したり、延性の
著しい低下を招くために3質量%を上限とした。好まし
くは、Mn:1.5〜3.0%とすることにより良好な
強度−穴拡げ性バランスが得られる。Mn is added for the purpose of increasing the strength. It is also effective in suppressing ferrite transformation and converting the main phase into bainite or bainitic ferrite. Further, it is added for the purpose of suppressing carbide precipitation, which is one of the causes of strength reduction and deterioration of hole expandability, and pearlite formation.
From these things, it was 0.01 mass% or more. on the other hand,
Excessive addition promotes martensite formation and causes a remarkable decrease in ductility, so the upper limit was 3% by mass. Preferably, by setting Mn: 1.5 to 3.0%, a good balance between strength and hole expandability can be obtained.
【0028】Pは、強化元素である。また、低P化は穴
拡げ性を向上させるが、極低化は経済的にも不利である
ことから0.0010質量%を下限とした。また、多量
添加では、溶接性や鋳造時や熱延時の製造性に悪影響を
及ぼすため、0.1%を上限とした。P is a strengthening element. Further, lowering P improves hole expandability, but extremely lowering is economically disadvantageous, so the lower limit was made 0.0010 mass%. Further, addition of a large amount adversely affects weldability and manufacturability during casting and hot rolling, so 0.1% was made the upper limit.
【0029】Sは、低S化は穴拡げ性向上に有効であ
る。一方、極低化は経済的に不利であることから、0.
0010質量%を下限とし、また、0.05質量%を上
限としたのは、これを超える量の添加では、溶接性や鋳
造時や熱延時の製造性に悪影響を及ぼすためである。As for S, lowering S is effective for improving hole expandability. On the other hand, since extremely low cost is economically disadvantageous,
The lower limit of 0010 mass% and the upper limit of 0.05 mass% are that addition of an amount exceeding this adversely affects weldability and manufacturability during casting and hot rolling.
【0030】Alは、脱酸元素として添加する。このた
め、0.005質量%以上の添加とした。一方過剰添加
は溶接性およびめっき濡れ性を損なうため4%を上限と
した。Al is added as a deoxidizing element. Therefore, the addition amount is set to 0.005 mass% or more. On the other hand, excessive addition impairs weldability and plating wettability, so 4% was made the upper limit.
【0031】Moは、強度−穴拡げ性バランスを劣化さ
せる炭化物やパーライトの生成を抑制する。また、フェ
ライト変態を抑制して、主相をベイナイトまたはベイニ
ティックフェライトにするのに有効であり、良好な強度
−穴拡げ性およびめっき材の溶接性や溶接後の疲労耐久
性の確保の極めて良好なバランスを得るための添加元素
であることから、その下限を0.01質量%とした。ま
た、過剰添加は、延性劣化を招くことから、上限を5.
0%とした。Mo suppresses the formation of carbides and pearlite which deteriorate the strength-hole expandability balance. Further, it suppresses ferrite transformation and is effective in making the main phase bainite or bainitic ferrite, and has excellent strength-hole expandability and weldability of the plated material and extremely high fatigue durability after welding. Since it is an additive element for obtaining a good balance, its lower limit is set to 0.01% by mass. Moreover, since excessive addition causes deterioration of ductility, the upper limit is set to 5.
It was set to 0%.
【0032】Nbは、微細な炭化物、窒化物または炭窒
化物を形成して、鋼板の強化に極めて有効である。ま
た、フェライト変態を遅滞させ、ベイナイトおよびベイ
ニティックフェライトの生成を助長する。さらには、溶
接熱影響部の軟化抑制にも効果的であることから、0.
001質量%以上の添加とし、0.01%以上の添加が
溶接性向上のためには好ましい。一方で、過剰添加は、
延性や熱間加工性を劣化させることから、上限として
1.0質量%とした。Nb forms fine carbides, nitrides or carbonitrides and is extremely effective in strengthening steel sheets. It also delays ferrite transformation and promotes the formation of bainite and bainitic ferrite. Furthermore, since it is also effective in suppressing the softening of the weld heat affected zone,
The addition amount is 001% by mass or more, and the addition amount of 0.01% or more is preferable for improving weldability. On the other hand, excessive addition is
Since ductility and hot workability are deteriorated, the upper limit was made 1.0% by mass.
【0033】また、800 MPa以上の強度レベルで、溶
接性および穴拡げ性をバランス良く、制御するために
は、式(A)を満足しなければならない。
3.0Nb+2.5Mo+Mn−5C0.5 > 0 ・・・(A)Further, in order to control the weldability and the hole expandability in a well-balanced manner at a strength level of 800 MPa or more, the formula (A) must be satisfied. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 ・ ・ ・ (A)
【0034】Nb、MoおよびMnは焼入れ性を向上さ
せ、さらにNbおよびMoは熱影響部の軟化防止に効果
的で、各係数はその程度を反映するものである。一方、
Cは効果に有効なものの、溶接時の軟化挙動を助長す
る。その機構の詳細については、明確になっていない
が、NbおよびMoの軟化防止効果は溶接熱サイクル中
に析出物形成やソリュウトドラッグ効果によると考えら
れる。一方、Cは焼入れ硬貨量が大きいうえ析出粗大化
を助長することから、熱影響部の軟化を含めた溶接性を
劣化させると考えられる。図1に示すように、式(A)
の左辺の値がゼロ以下の領域では、たとえベイナイトま
たはベイニティックフェライトの面積率が70%以上とし
ても、疲労強度比−引張り強度−穴拡げ率:λの両立し
た良好な材質は得られないことがわかる(図1中×
印)。また、式(A)の左辺の値がゼロ超の領域におい
ても、製造方法の違いからベイナイトおよびベイニティ
ックフェライトの面積率が低いものは、良好な材質が得
られないこともわかる(図1中*印)。すなわち、組織
および式(A)の条件を同時に満たすもののみ良好な材
質が得られることがわかる。Nb, Mo and Mn improve hardenability, and Nb and Mo are effective in preventing softening of the heat-affected zone, and each coefficient reflects the degree. on the other hand,
Although C is effective for the effect, it promotes the softening behavior during welding. Although the details of the mechanism have not been clarified, it is considered that the softening preventing effect of Nb and Mo is due to the formation of precipitates or the solution drag effect during the welding thermal cycle. On the other hand, since C has a large amount of hardened coins and promotes precipitation coarsening, it is considered that C deteriorates weldability including softening of the heat-affected zone. As shown in FIG. 1, the formula (A)
In the region where the value on the left side of is less than or equal to zero, even if the area ratio of bainite or bainitic ferrite is 70% or more, it is not possible to obtain a good material that satisfies both fatigue strength ratio-tensile strength-hole expansion ratio: λ. You can see that
mark). Further, even in the region where the value on the left side of the formula (A) is more than zero, it is found that good materials cannot be obtained if the area ratio of bainite and bainitic ferrite is low due to the difference in manufacturing method (FIG. 1). Middle *). That is, it is understood that a good material can be obtained only when the structure and the condition of the formula (A) are simultaneously satisfied.
【0035】また、めっき性を確保して、より良好な耐
食性を確保する目的から、式(B)を満たさなければな
らない。
Al+15.0Si2 +1.5Si-1.8 < 0 ・・・(B)Further, the formula (B) must be satisfied for the purpose of ensuring plating property and better corrosion resistance. Al + 15.0Si 2 + 1.5Si-1.8 <0 ・ ・ ・ (B)
【0036】AlおよびSiはめっきの濡れ性や合金化
挙動に影響を及ぼす。特に濡れ性を劣化させ、各係数は
その程度を反映するものである。その機構の詳細につい
ては、明確になっていないが、表面に形成される酸化物
を形態に起因していると考えられる。図2に示すよう
に、式(B)の左辺の値がゼロ以上の領域では、耐食性
試験後の外観評点が低くく、耐食性に劣る。また、式
(B)の左辺の値がゼロ未満の領域においても、製造方
法の違いから耐食性に劣るものもある。Al and Si affect the wettability of the plating and the alloying behavior. In particular, the wettability is deteriorated, and each coefficient reflects the degree. Although the details of the mechanism are not clear, it is considered that the oxide formed on the surface is caused by the morphology. As shown in FIG. 2, in the region where the value on the left side of the formula (B) is zero or more, the appearance score after the corrosion resistance test is low and the corrosion resistance is poor. Even in the region where the value on the left side of the formula (B) is less than zero, the corrosion resistance may be poor due to the difference in manufacturing method.
【0037】さらに、本発明が対象とする鋼は、強度−
穴拡げ性バランスのさらなる向上を目的として、Cr、
Ni、Cu1種または2種以上を含有できる。Crは、
強化目的および炭化物生成の抑制とベイナイトおよびベ
イニティックフェライト生成の目的から添加する元素
で、0.01%以上とし、5%を超える量の添加では、
加工性やめっき性に悪影響を及ぼすため、これを上限と
した。Niは、焼き入れ性の向上およびめっき性向上の
目的で0.01質量%以上とし、5質量%を超える量の
添加では、加工性、特にマルテンサイト生成に伴うの硬
度上昇寄与して悪影響を及ぼすため、これを上限とし
た。Cuは、強化およびめっき性向上の目的で0.01
質量%以上の添加とし、5質量%を超える量の添加で
は、加工性および製造性に悪影響を及ぼす。Further, the steel targeted by the present invention has strength
For the purpose of further improving the balance of hole expandability, Cr,
Ni, Cu 1 type, or 2 or more types can be contained. Cr is
It is an element added for the purpose of strengthening and suppressing the formation of carbides and the purpose of forming bainite and bainitic ferrite, and is 0.01% or more, and when added in an amount exceeding 5%,
This has an upper limit because it adversely affects workability and plating properties. Ni is 0.01% by mass or more for the purpose of improving the hardenability and the plating property, and if added in an amount of more than 5% by mass, it contributes to the workability, especially the increase in hardness associated with the formation of martensite, which has an adverse effect. Therefore, this is set as the upper limit. Cu is 0.01 for the purpose of strengthening and improving plating property.
Addition of more than 5% by mass will adversely affect workability and manufacturability.
【0038】また、めっき性の確保に関しては、より良
好な耐食性を確保する目的から、式(C)を満たさなけ
ればならない。
Al+15.0Si2 +1.5Si +0.5Cr −(30Ni +10Cu) −1.8 < 0 ・・・(C)Further, with respect to ensuring the plating property, the formula (C) must be satisfied for the purpose of ensuring better corrosion resistance. Al + 15.0Si 2 + 1.5Si + 0.5Cr - (30Ni + 10Cu) -1.8 <0 ··· (C)
【0039】上述のように、CrはAlやSiと同様、
表面の酸化物形態に影響するためめっき性を劣化させ
る。一方、NiおよびCuはめっき性改善に有効であ
り、各係数はその程度を反映するものである。したがっ
て、Cr、NiやCuを含む場合には、(B)式でなく
(C)式を満たさなければならない。図3に示すよう
に、式(C)の左辺の値がゼロ以上の領域では、めっき
外観評点が低く、一方、式(C)の左辺の値がゼロ未満
の領域ではすべて良好なめっき外観評点が得られる。As described above, Cr is similar to Al and Si,
Since it affects the oxide morphology on the surface, it deteriorates the plating property. On the other hand, Ni and Cu are effective in improving the plating property, and each coefficient reflects the degree thereof. Therefore, when Cr, Ni, or Cu is included, the formula (C) must be satisfied instead of the formula (B). As shown in FIG. 3, the plating appearance score is low in the region where the value on the left side of the formula (C) is zero or more, while the plating appearance score is all good in the region where the value on the left side of the formula (C) is less than zero. Is obtained.
【0040】さらには、Co、Wの1種または2種以上
を含有できる。Coは、ベイナイト変態制御による強度
−穴拡げ性の良好なバランスのため、0.01質量%以
上の添加とした。一方、添加の上限は特に設けないが、
高価な元素であるため多量添加は経済性を損なうため、
5質量%以下にすることが望ましい。Wは、0.01質
量%以上で強化効果が現れること、5質量%を上限とし
たのは、これを超える量の添加では、加工性に悪影響を
及ぼすためである。Furthermore, one or more of Co and W can be contained. Co is added in an amount of 0.01% by mass or more in order to achieve a good balance of strength and hole expansibility by controlling bainite transformation. On the other hand, although the upper limit of addition is not particularly set,
Since it is an expensive element, adding a large amount impairs economic efficiency.
It is desirable that the content be 5 mass% or less. W has a strengthening effect when it is 0.01 mass% or more, and the upper limit of 5 mass% is that addition of an amount exceeding this adversely affects workability.
【0041】さらに、本発明が対象とする鋼は、強度の
さらなる向上を目的として強炭化物形成元素であるZ
r、Hf、Ta、Ti、Vの1種または2種以上を含有
できる。これらの元素は、微細な炭化物、窒化物または
炭窒化物を形成して、鋼板の強化に極めて有効であるた
め、必要に応じて1種または2種以上を合計で0.00
1質量%以上の添加とした。一方で、延性や熱間加工性
の劣化を招くことから、1種または2種以上の合計添加
量の上限として1質量%とした。Further, the steel targeted by the present invention is Z which is a strong carbide forming element for the purpose of further improving the strength.
It may contain one or more of r, Hf, Ta, Ti and V. These elements form fine carbides, nitrides or carbonitrides and are extremely effective in strengthening the steel sheet. Therefore, if necessary, one kind or two or more kinds in total of 0.00
The addition was 1 mass% or more. On the other hand, since ductility and hot workability are deteriorated, the upper limit of the total addition amount of one or more kinds is set to 1% by mass.
【0042】Bもまた、必要に応じて添加できる。B
は、0.0001質量%以上の添加で粒界の強化や鋼材
の高強度化に有効ではあるが、その添加量が0.1質量
%を超えるとその効果が飽和するばかりでなく、加工性
が低下するため、上限を0.1質量%とした。B can also be added if necessary. B
Is effective in strengthening the grain boundaries and increasing the strength of steel by adding 0.0001 mass% or more, but if the addition amount exceeds 0.1 mass%, not only the effect is saturated, but also the workability is improved. Therefore, the upper limit was made 0.1 mass%.
【0043】Ca、Y、Remは、適量添加により介在
物制御、特に微細分散化に寄与することから0.000
1%以上とし、一方で過剰添加は鋳造性や熱間加工性な
どの製造性および鋼板製品の延性を低下させるため0.
5質量%を上限とした。不可避的不純物として、例えば
NやSnなどがあるがこれら元素を0.02質量%以下
の範囲で含有しても本発明の効果を損なうものではな
い。When Ca, Y and Rem are added in appropriate amounts, they contribute to the control of inclusions, particularly to fine dispersion, so 0.000.
1% or more, while excessive addition lowers manufacturability such as castability and hot workability and the ductility of steel sheet products.
The upper limit was 5% by mass. Examples of unavoidable impurities include N and Sn, but the inclusion of these elements in the range of 0.02 mass% or less does not impair the effects of the present invention.
【0044】このような組織を有する溶接性、穴拡げ性
に優れた高強度鋼板およびの製造方法について以下に説
明する。熱延後冷延・焼鈍して本発明の鋼板を製造する
場合には、所定の成分に調整されたスラブを直接もしく
は一旦冷却した後再加熱して熱延を行う。A method for producing a high-strength steel sheet having such a structure and excellent in weldability and hole expandability will be described below. When the steel sheet of the present invention is manufactured by cold rolling and annealing after hot rolling, the slab adjusted to have the predetermined components is directly or once cooled and then reheated to perform hot rolling.
【0045】このときの再加熱温度は1100℃以上1
300℃以下とすることが望ましい。再加熱温度が高温
になると粗粒化や厚い酸化スケールが形成され、一方、
低温加熱では圧延抵抗が高くなってしまう。また熱延後
は、高圧デスケーリング装置や酸洗することなどで表面
スケール削除を行うと製品での表面清浄がよくなり、め
っきを施す場合などに有利である。その後、冷延後焼鈍
することで最終製品とする。また、電気めっきや溶融亜
鉛めっき、溶融合金亜鉛めっきを施しても本願発明を阻
害するものではない。また、熱延完了温度は鋼の化学成
分によって決まるAr3 変態温度以上で行うのが一般的
であるが、Ar3 から10℃程度低温までであれば最終
的な鋼板の特性を劣化させない。また、冷却後の巻取温
度は鋼の化学成分によって決まるベイナイト変態開始温
度以上とすることで、冷延時の荷重を必要以上に高める
ことがさけられるが、冷延の全圧下率が小さい場合には
この限りでなく、鋼のベイナイト変態温度以下で巻き取
られても最終的な鋼板の特性を劣化させない。また、冷
延の全圧下率は、最終板厚と冷延荷重の関係から設定さ
れるが、40%以上であれば再結晶させるには十分で、
最終的な鋼板の特性を劣化させない。The reheating temperature at this time is 1100 ° C. or higher 1
It is desirable that the temperature be 300 ° C. or lower. When the reheating temperature becomes high, coarse grains and thick oxide scale are formed, while
Rolling resistance increases with low temperature heating. Further, after hot rolling, if the surface scale is removed by a high pressure descaling device or pickling, the surface of the product can be cleaned well, which is advantageous when plating is applied. After that, the product is finished by cold rolling and annealing. In addition, electroplating, hot dip galvanizing, and hot dip galvanizing do not hinder the present invention. Further, the hot rolling completion temperature is generally set to an Ar 3 transformation temperature or higher determined by the chemical composition of the steel, but if the temperature is from Ar 3 to a low temperature of about 10 ° C., the properties of the final steel sheet will not be deteriorated. In addition, the coiling temperature after cooling is higher than the bainite transformation start temperature, which is determined by the chemical composition of the steel, to prevent the load during cold rolling from being increased more than necessary, but when the total reduction rate of cold rolling is small. Is not limited to this, and the properties of the final steel sheet will not be deteriorated even if wound at a temperature below the bainite transformation temperature of the steel. Further, the total reduction ratio of cold rolling is set from the relationship between the final plate thickness and the cold rolling load, but if it is 40% or more, it is sufficient for recrystallization,
Does not deteriorate the properties of the final steel sheet.
【0046】冷延後焼鈍する際に、焼鈍温度が鋼の化学
成分によって決まる温度Ac1 およびAc3 温度(例え
ば「鉄鋼材料学」:W.C.Leslie著、幸田成康
監訳、丸善P273)で、表現される0.3×(Ac3
−Ac1 )+Ac1 (℃)未満の場合には、焼鈍温度で
得られるオーステナイト量が少ないので、最終的な鋼板
中に主にベイナイトまたはベイニティックフェライトを
生成させることができない。また、焼鈍温度が高温とな
るほど結晶粒の粗大化や表面酸化が促進されるうえ、製
造コストの上昇をまねくために、焼鈍温度の上限をAc
3 +30(℃)とした。この温度域での焼鈍時間は鋼板の
温度均一化とオーステナイトの確保のために10秒以上
が必要である。しかし、30分超では、粒界酸化相生成
が促進されるうえ、コストの上昇を招く。ここで、昇温
および焼鈍時の雰囲気が酸素濃度が50ppm 以下で露点
が−20℃以下とした。酸素濃度が50ppm を超えた
り、露点がー20℃を超えると、鋼板のめっき性、特に
濡れ性が劣化し、不めっきの原因となる。When annealing after cold rolling, at the temperatures Ac 1 and Ac 3 where the annealing temperature is determined by the chemical composition of the steel (for example, "Steel Material Science": W. C. Leslie, translated by Shigeyasu Koda, Maruzen P273). , Expressed as 0.3 × (Ac 3
If it is less than −Ac 1 ) + Ac 1 (° C.), the amount of austenite obtained at the annealing temperature is small, so that bainite or bainitic ferrite cannot be mainly produced in the final steel sheet. In addition, the higher the annealing temperature is, the larger the grain size and surface oxidation are promoted, and the upper limit of the annealing temperature is set to Ac in order to increase the manufacturing cost.
It was set to 3 + 30 (° C). The annealing time in this temperature range needs to be 10 seconds or more to make the temperature of the steel plate uniform and to secure austenite. However, if it exceeds 30 minutes, the generation of the grain boundary oxidized phase is promoted and the cost is increased. Here, the atmosphere at the time of temperature rising and annealing had an oxygen concentration of 50 ppm or less and a dew point of -20 ° C or less. If the oxygen concentration exceeds 50 ppm or the dew point exceeds −20 ° C., the plateability of the steel sheet, particularly the wettability, deteriorates, causing non-plating.
【0047】その後の一次冷却はオーステナイト相から
フェライト相への変態をある程度抑しつつ、ベイナイト
またはベイニティックフェライト生成させるのに重要で
ある。この冷却速度を0.1℃/秒未満にすることは、
フェライトやパーライトの生成を促進して強度低下を招
く懸念があることから、冷却速度の下限を0.1℃/秒
とした。一方、冷却速度が100℃/秒超の場合には最
終的な鋼板中のマルテンサイト相などの硬質相が多量に
なってしまうことや、操業上困難なため、これを上限と
した。The subsequent primary cooling is important for producing bainite or bainitic ferrite while suppressing the transformation from the austenite phase to the ferrite phase to some extent. Setting this cooling rate to less than 0.1 ° C./sec
The lower limit of the cooling rate was set to 0.1 ° C./second because there is a concern that the generation of ferrite or pearlite may be promoted and the strength may be reduced. On the other hand, when the cooling rate is more than 100 ° C./sec, the hard steel plate has a large amount of hard phase such as martensite phase in the final steel plate, and it is difficult in operation.
【0048】この後の冷却がめっき浴温度−20℃未満
まで行われると、めっき浴浸入時の抜熱が大きいことな
どの操業上の問題がある。また、冷却停止温度がめっき
浴+50℃を超えると、操業上の問題に加え、その後の
保持時に炭化物が生成してしまい、強度低下を招くた
め、これを上限とした。また、次にベイナイト変態の進
行を促すため、この温度域での保持を行う。この停留時
間が長時間になると生産性上好ましくないうえ、炭化物
が生成してしまうことから1000秒以内とすることが
望ましい。また、ベイナイト変態進行させるため、1秒
以上保持し、好ましくは15秒から10分保持すること
が望ましい。めっき浴温度−20℃未満ではベイナイト
変態が起こりにくく、めっき浴温度−50℃を超えると
炭化物が生じて材質劣化してしまう。また、合金化処理
を行う場合には、430℃以上580℃以下とした。合
金化処理温度が430℃未満であると合金化の進行が遅
く、生産性が悪い。また、580℃を超えると炭化物析
出を伴い、材質劣化する。また、溶接方法については、
通常行われる溶接方法、たとえばアーク、TIG 、MIG 、
マッシュおよびレーザー等の溶接を行っても本願の範囲
とする。If the subsequent cooling is carried out until the plating bath temperature is lower than -20 ° C., there is a problem in operation such as a large heat removal during the immersion of the plating bath. Further, when the cooling stop temperature exceeds + 50 ° C. in the plating bath, in addition to problems in operation, carbides are generated during the subsequent holding, which causes a decrease in strength, so this was made the upper limit. Further, in order to promote the progress of bainite transformation, the temperature is maintained in this temperature range. It is desirable to set the retention time to 1000 seconds or less, because if the retention time is long, it is not preferable in terms of productivity and carbide is generated. Further, in order to allow the bainite transformation to proceed, it is desirable to hold for 1 second or more, preferably 15 seconds to 10 minutes. If the plating bath temperature is lower than -20 ° C, bainite transformation is unlikely to occur, and if the plating bath temperature exceeds -50 ° C, carbides are generated and the material is deteriorated. Moreover, when performing an alloying process, it was 430 degreeC or more and 580 degreeC or less. If the alloying temperature is lower than 430 ° C., the progress of alloying is slow and the productivity is poor. Further, if the temperature exceeds 580 ° C, the material is deteriorated along with the precipitation of carbide. Also, regarding the welding method,
Welding methods that are commonly used, such as arc, TIG, MIG,
It is within the scope of the present application even if welding such as mash and laser is performed.
【0049】[0049]
【実施例】以下、実施例によって本発明をさらに詳細に
説明する。表1に示すような組成の鋼板を、1200℃
に加熱し、Ar3 変態温度以上で熱延を完了し、冷却後
各鋼の化学成分で決まるベイナイト変態開始温度以上で
巻き取った鋼帯を酸洗後、冷延して1.2mm厚とし
た。その後、各鋼の成分(質量%)から下記式にしたが
ってAc1 とAc3 変態温度を計算により求めた。
Ac1 =723−10.7×Mn%+29.1×Si
%、
Ac3 =910−203×(C%)1/2 −15.2×
Ni%+44.7×Si%+104×V%+31.5×
Mo%−30×Mn%−11×Cr%+400×Al
%、
これらのAc1 およびAc3 変態温度から計算される焼
鈍温度に10%H2 −N2 雰囲気中で昇温・保定したの
ち、3〜150℃/秒の冷却速度で200〜450℃ま
で冷却し、引き続いて1〜3000秒保持した後、冷却
した。The present invention will be described in more detail with reference to the following examples. A steel plate having a composition as shown in Table 1 is 1200 ° C.
After completion of hot rolling at the Ar 3 transformation temperature or higher, after cooling, the steel strip wound at the bainite transformation start temperature or higher determined by the chemical composition of each steel is pickled and then cold rolled to a thickness of 1.2 mm. did. Then, the Ac 1 and Ac 3 transformation temperatures were calculated from the components (mass%) of each steel according to the following formulas. Ac 1 = 723-10.7 × Mn% + 29.1 × Si
%, Ac 3 = 910−203 × (C%) 1 / 2−15.2 ×
Ni% + 44.7 × Si% + 104 × V% + 31.5 ×
Mo% -30 x Mn% -11 x Cr% + 400 x Al
%, The annealing temperature calculated from these Ac 1 and Ac 3 transformation temperatures is raised and held in a 10% H 2 —N 2 atmosphere, and then 200 to 450 ° C. at a cooling rate of 3 to 150 ° C./sec. It was cooled and then held for 1-3000 seconds and then cooled.
【0050】これらの鋼板からJIS 5号引張り試験片を
採取して、機械的性質を測定した。さらに、鉄鋼連盟規
格に準拠して穴拡げ試験を行い、穴拡げ率を求めた。溶
接性については鋼板にビードオンの形で各溶接を行い、
弗素系樹脂(テフロン 商品名)潤滑にて球頭張り出し
試験を行い、母材に対する張り出し高さおよび破断位置
を測定した。また、各溶接継ぎ手を作成して、引張り−
引張りモードの疲労試験を105 〜106 cyclesまで行い、
母材との疲労強度を比較することでめっき材の溶接継ぎ
手の疲労特性を比較評価した。ここで、溶接継ぎ手は、
ビードオンで行い、溶接後、試験片端面および表面を研
削して溶接チャンスによる継ぎ手形状のばらつき因子を
極力少なくする方法を採った。また、めっき性の試験
は、外観観察して5段階の評点をつけた。また、めっき
後の耐食性試験には、板厚の3倍の曲率半径で板を曲げ
たあとで乾湿繰り返し試験を行い、その発錆の程度をや
はり5段階で評価した。JIS No. 5 tensile test pieces were taken from these steel sheets and their mechanical properties were measured. Further, a hole expansion test was conducted in accordance with the Iron and Steel Federation standards to obtain the hole expansion ratio. Regarding weldability, each weld was performed on the steel plate in a bead-on form,
A ball head overhanging test was carried out with a fluorine resin (Teflon brand name) lubrication, and the overhanging height and breaking position relative to the base material were measured. Also, make each welding joint and pull
Perform tensile mode fatigue test for 10 5 to 10 6 cycles,
By comparing the fatigue strength with the base material, the fatigue characteristics of the welded joint of the plated material were comparatively evaluated. Where the weld joint is
The method was bead-on, and after welding, the end surface and surface of the test piece were ground to minimize the variation factor of the joint shape due to the welding chance. Further, in the plating property test, the appearance was observed and a rating of 5 levels was given. For the corrosion resistance test after plating, the plate was bent at a radius of curvature three times the plate thickness, and then a dry-wet repeated test was performed, and the degree of rusting was also evaluated in five stages.
【0051】表2にミクロ組織と各材質について、また
表3に各製造条件と材質について示す。本願発明の要綱
を満たす発明鋼は、溶接性、延性、強度(引張り強度で
800MPa以上)、穴拡げ性に優れていることがわか
る。一方、本発明の条件から外れる比較例は、溶接部の
球頭張り出加工における破断位置が溶接熱影響部とな
り、疲労強度も低く、穴拡げ性やめっき性や耐食性も劣
勢である。Table 2 shows the microstructure and each material, and Table 3 shows each manufacturing condition and material. Inventive steel satisfying the outline of the present invention has weldability, ductility, strength (tensile strength
800 MPa or more), which shows that the hole expandability is excellent. On the other hand, in Comparative Examples that deviate from the conditions of the present invention, the fracture position in the ball head overhanging process of the welded part becomes the weld heat affected zone, the fatigue strength is low, and the hole expandability, plating property and corrosion resistance are inferior.
【0052】[0052]
【表1】 [Table 1]
【0053】[0053]
【表2】 [Table 2]
【0054】[0054]
【表3】 [Table 3]
【0055】[0055]
【発明の効果】本発明により、引張り強度が800 MPa
以上の高強度鋼板の溶接性、穴拡げ性および耐食性を同
時に改善した溶融亜鉛めっき高強度鋼板およびその製造
方法を得ることができる。According to the present invention, the tensile strength is 800 MPa.
It is possible to obtain the hot-dip galvanized high-strength steel sheet and the manufacturing method thereof in which the weldability, hole expandability, and corrosion resistance of the above high-strength steel sheet are simultaneously improved.
【図面の簡単な説明】[Brief description of drawings]
【図1】 疲労強度比×引張り強度×λ(穴拡げ率)と
(A)式の左辺の値との関係を示すグラフである。FIG. 1 is a graph showing the relationship between fatigue strength ratio × tensile strength × λ (hole expansion ratio) and the value on the left side of the expression (A).
【図2】 乾湿繰り返し腐食試験後の外観評点と(B)
式の左辺の値との関係を示すグラフである。[Fig. 2] Appearance score after dry and wet repeated corrosion test and (B)
It is a graph which shows the relationship with the value of the left side of a formula.
【図3】 めっき外観評点と(C)式の左辺の値との関
係を示すグラフである。FIG. 3 is a graph showing the relationship between the plating appearance rating and the value on the left side of the expression (C).
───────────────────────────────────────────────────── フロントページの続き (51)Int.Cl.7 識別記号 FI テーマコート゛(参考) C23C 2/28 C23C 2/28 (72)発明者 松村 賢一郎 愛知県東海市東海町5−3 新日本製鐵株 式会社名古屋製鐵所内 (72)発明者 原 卓也 千葉県富津市新富20−1 新日本製鐵株式 会社技術開発本部内 (72)発明者 野中 俊樹 愛知県東海市東海町5−3 新日本製鐵株 式会社名古屋製鐵所内 Fターム(参考) 4K027 AA05 AA23 AB02 AB05 AB13 AB42 AC73 4K037 EA01 EA02 EA05 EA06 EA09 EA10 EA11 EA13 EA15 EA16 EA17 EA19 EA20 EA23 EA25 EA27 EA28 EA29 EA31 EA32 EA33 EA35 EA36 EB06 EB07 EB08 EB09 EB11 FA00 FB00 FG00 FH00 FJ02 FJ04 FJ05 FK01 FK02 FK03 GA05 GA08 JA01 ─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. 7 Identification code FI theme code (reference) C23C 2/28 C23C 2/28 (72) Inventor Kenichiro Matsumura 5-3 Tokai-cho, Tokai-shi, Aichi Pref. (72) Inventor Takuya Hara, Steel Works Co., Ltd. (72) Tatsuya Hara 20-1 Shintomi, Futtsu City, Chiba Prefecture Nippon Steel Co., Ltd. Technology Development Division (72) Inventor Toshiki Nonaka 5-3 Shinkai, Tokai City, Aichi Prefecture Nippon Steel Co., Ltd.Nagoya Steel F-Term (Reference) 4K027 AA05 AA23 AB02 AB05 AB13 AB42 AC73 4K037 EA01 EA02 EA05 EA06 EA09 EA10 EA11 EA13 EA15 EA16 EA17 EA35 EA35 EA35 EA35 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA32 EA31 EB09 EB11 FA00 FB00 FG00 FH00 FJ02 FJ04 FJ05 FK01 FK02 FK03 GA05 GA08 JA01
Claims (8)
(A)および(B)式を同時に満たす範囲で含有し、残
部をFeおよび不可避的不純物とし、ミクロ組織が、ベイ
ナイトまたはベイニティックフェライトとして面積率で
70%以上含有し、引張強度が800MPa以上であることを
特徴とする溶接性、穴拡げ性および耐食性に優れた溶融
亜鉛めっき高強度鋼板。 3.0Nb+2.5Mo+Mn −5C0.5 > 0 ・・・(A) Al+15.0Si2 +1.5Si-1.8 < 0 ・・・(B)1. In mass%, C: 0.01 to 0.20%, Si: 1.5% or less, Mn: 0.01 to 3%, P: 0.0010 to 0.1%, S: 0.0010 to 0.05%, Al: 0.005 to 4% is contained, and further, Mo: 0.01 to 5.0%, Nb: 0.001 to 1.0%, one or two kinds. In the range that simultaneously satisfies the following formulas (A) and (B), with the balance being Fe and inevitable impurities, the microstructure containing 70% or more in area ratio as bainite or bainitic ferrite, and having a tensile strength A hot-dip galvanized high-strength steel sheet with excellent weldability, hole expandability, and corrosion resistance that is characterized by 800 MPa or more. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 ・ ・ ・ (A) Al + 15.0Si 2 + 1.5Si-1.8 <0 ・ ・ ・ (B)
ることを特徴とし、さらに式(A)および(C)を満た
す請求項1に記載(ただし本項では式(B)を満たす必
要はない)の溶接性、穴拡げ性および耐食性に優れた溶
融亜鉛めっき高強度鋼板。 3.0Nb+2.5Mo+Mn−5C0.5 > 0 ・・・(A) Al+15.0Si2 +1.5Si +0.5Cr −(30Ni +10Cu) −1.8 < 0 ・・・(C)2. Further, in mass%, one or more of Cr: 0.01 to 5%, Ni: 0.01 to 5%, and Cu: 0.01 to 5% are contained. A hot-dip galvanizing height which is excellent in weldability, hole expansibility and corrosion resistance as set forth in claim 1 (but it is not necessary to satisfy the formula (B) in this paragraph), which further satisfies the formulas (A) and (C). Strength steel plate. 3.0Nb + 2.5Mo + Mn-5C 0.5 > 0 ・ ・ ・ (A) Al + 15.0Si 2 + 1.5Si + 0.5Cr − (30Ni + 10Cu) −1.8 <0 ・ ・ ・ (C)
ことを特徴とする請求項1または請求項2に記載の溶接
性、穴拡げ性および耐食性に優れた溶融亜鉛めっき高強
度鋼板。3. The composition according to claim 1, further comprising, in mass%, one or more of Co: 0.01 to 5% and W: 0.01 to 5%. The hot-dip galvanized high-strength steel sheet excellent in weldability, hole expandability, and corrosion resistance described in.
計で0.001〜1%含有することを特徴とする請求項
1乃至請求項3に記載の溶接性、穴拡げ性および耐食性
に優れた溶融亜鉛めっき高強度鋼板。4. Further, 0.001 to 1% of Zr, Hf, Ta, Ti, and V in total of 0.001 to 1% by mass is contained. The hot-dip galvanized high-strength steel sheet excellent in weldability, hole expandability, and corrosion resistance described in.
0.1%を含有することを特徴とする請求項1乃至請求
項4に記載の溶接性、穴拡げ性および耐食性に優れた溶
融亜鉛めっき高強度鋼板。5. Further, B: 0.0001 to% by mass.
The hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance according to any one of claims 1 to 4, which contains 0.1%.
種または2種以上を合計で0.0001〜0.5%含有
することを特徴とする請求項1乃至請求項5に記載の溶
接性、穴拡げ性および耐食性に優れた溶融亜鉛めっき高
強度鋼板。6. Further, in mass%, 1 of Ca, Y and Rem is used.
Type or two or more types in total 0.0001 to 0.5% is contained, The hot-dip galvanized high-strength steel sheet excellent in weldability, hole expandability and corrosion resistance according to claim 1 to 5, .
なる鋳造スラブを直接または一旦冷却した後に再度加熱
し、熱延後巻取った熱延鋼板を酸洗後冷延し、その後昇
温および焼鈍時の雰囲気が酸素濃度が50ppm 以下で露
点が−20℃以下とし、焼鈍時の最高温度が0.3×
(Ac3 −Ac1 )+Ac1 (℃)以上Ac3 +30
(℃)以下で焼鈍した後に、0.1〜100℃/秒の冷
却速度で亜鉛めっき浴温度−20℃〜亜鉛めっき浴温度
+50℃の温度域に冷却し、引き続いて同温度域でめっ
き浸漬を含めて1秒〜1000秒保持を行うことを特徴とす
る溶接性、穴拡げ性および耐食性に優れた溶融亜鉛めっ
き高強度鋼板の製造方法。7. A cast slab comprising the components of claims 1 to 6 is directly or once cooled and then reheated, the hot rolled steel sheet is hot rolled after pickling, cold rolled after pickling, and then raised. The temperature and the atmosphere during annealing have an oxygen concentration of 50 ppm or less and a dew point of -20 ° C or less, and the maximum temperature during annealing is 0.3 x.
(Ac 3 −Ac 1 ) + Ac 1 (° C.) or more Ac 3 +30
After annealing at (° C.) or lower, it is cooled at a cooling rate of 0.1 to 100 ° C./sec to a temperature range of zinc plating bath temperature −20 ° C. to zinc plating bath temperature + 50 ° C., followed by plating immersion in the same temperature range. The method for producing a hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance, which is characterized by holding for 1 second to 1000 seconds.
鉛めっき浴温度−20℃〜亜鉛めっき浴温度+50℃の
温度域に冷却し、引き続いて同温度域でめっき浸漬を含
めて1秒〜1000秒保持後、合金化処理を430℃〜58
0℃を行うことを特徴とする溶接性、穴拡げ性および耐
食性に優れた溶融亜鉛めっき高強度鋼板の製造方法。8. The manufacturing method according to claim 7, wherein the temperature is cooled to a temperature range of zinc plating bath temperature −20 ° C. to zinc plating bath temperature + 50 ° C., and subsequently 1 second including plating immersion in the same temperature region. After holding for 1000 seconds, alloying treatment is performed at 430 ° C to 58
A method for producing a hot-dip galvanized high-strength steel sheet having excellent weldability, hole expandability, and corrosion resistance, which is characterized by performing 0 ° C.
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