JP6922857B2 - Fused Al-Si plated steel sheet and its manufacturing method - Google Patents
Fused Al-Si plated steel sheet and its manufacturing method Download PDFInfo
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本発明は、溶融Al-Si系めっき鋼板及びその製造方法に関する。 The present invention relates to a molten Al—Si-based plated steel sheet and a method for producing the same.
耐食性に優れる溶融Al-Si系めっき鋼板は、長期間屋外に曝される屋根や壁等の建材分野を中心に需要が伸び、近年は自動車分野においても優れた耐熱性を活かしてマフラーや燃料タンク等の特定部品で使用されている。特に自動車分野においては、地球温暖化対策の一環として、車体を軽量化することによって燃費を向上させることによりCO2排出量を削減することが求められている。このため、現在、高強度鋼板の使用による軽量化と鋼板の耐食性向上によるゲージダウンとが強く望まれている。 Demand for hot-dip Al-Si-based galvanized steel sheets with excellent corrosion resistance has increased mainly in the field of building materials such as roofs and walls that are exposed to the outdoors for a long period of time. It is used in specific parts such as. In particular, in the field of automobiles, as part of measures against global warming, it is required to reduce CO 2 emissions by improving fuel efficiency by reducing the weight of the vehicle body. Therefore, at present, it is strongly desired to reduce the weight by using a high-strength steel sheet and to reduce the gauge by improving the corrosion resistance of the steel sheet.
しかしながら、溶融Al-Si系めっき鋼板を自動車分野、特に外板パネル等の車体に用いようとした場合、化成処理性が劣るため、亜鉛めっき鋼板と比べ塗装後耐食性が劣位となるという課題があった。 However, when a molten Al-Si-based plated steel sheet is used in the automobile field, especially for a vehicle body such as an outer panel, there is a problem that the corrosion resistance after painting is inferior to that of a galvanized steel sheet because the chemical conversion treatment property is inferior. rice field.
本発明は、上記課題に鑑みてなされたものであって、その目的は、化成処理性を向上させることにより塗装後耐食性を改善可能な溶融Al-Si系めっき鋼板及びその製造方法を提供することにある。 The present invention has been made in view of the above problems, and an object of the present invention is to provide a molten Al-Si-based galvanized steel sheet capable of improving post-coating corrosion resistance by improving chemical conversion treatment property and a method for producing the same. It is in.
本発明に係る溶融Al-Si系めっき鋼板は、鋼板の表面に形成された、少なくともAl,Si,及びFeを含有する界面合金層と、前記界面合金層の表面に形成された、少なくともAl,Si,及びCuを含有するめっき層と、を有し、前記めっき層のSi含有率が原子%濃度で1%以上13%以下の範囲内にあることを特徴とする。 The molten Al—Si-based plated steel sheet according to the present invention has an interfacial alloy layer containing at least Al, Si, and Fe formed on the surface of the steel sheet and at least Al, formed on the surface of the interfacial alloy layer. It has a plating layer containing Si and Cu, and the Si content of the plating layer is in the range of 1% or more and 13% or less in terms of atomic% concentration.
本発明に係る溶融Al-Si系めっき鋼板は、上記発明において、前記めっき層のCu含有率が原子%濃度で0.05%以上3%以下の範囲内にあることを特徴とする。 The molten Al—Si-based plated steel sheet according to the present invention is characterized in that, in the above invention, the Cu content of the plating layer is in the range of 0.05% or more and 3% or less in terms of atomic% concentration.
本発明に係る溶融Al-Si系めっき鋼板は、上記発明において、前記めっき層がMg,Ca,Ti,Mn,Znの中から選ばれる1種以上の元素をそれぞれの原子%濃度の合計で10%以下の範囲内含有することを特徴とする。 In the molten Al—Si-based plated steel sheet according to the present invention, in the above invention, the plating layer contains one or more elements selected from Mg, Ca, Ti, Mn, and Zn, and the total atomic% concentration of each element is 10. It is characterized by containing within the range of% or less.
本発明に係る溶融Al-Si系めっき鋼板は、上記発明において、X線回折で得られるAl相[111]の回折強度{I(Al)}に対するAl2Cu相[222]の回折強度{I(Al2Cu)}のメインピーク強度の比率Y=I(Al2Cu)/I(Al)が0.02以下であることを特徴とする。 In the above invention, the molten Al—Si based plated steel sheet according to the present invention has a diffraction intensity {I of the Al 2 Cu phase [222] with respect to the diffraction intensity {I (Al)} of the Al phase [111] obtained by X-ray diffraction. (Al 2 Cu)} is characterized in that the ratio Y = I (Al 2 Cu) / I (Al) of the main peak intensity is 0.02 or less.
本発明に係る溶融Al-Si系めっき鋼板の製造方法は、本発明に係る溶融Al-Si系めっき鋼板の製造方法であって、いずれも原子%濃度でSi:1%以上13%以下、Fe:2%以下、Cu:0.05%以上3%以下、Mg,Ca,Ti,Mn,Znの中から選ばれる1種以上の元素を合計で10%以下の範囲内含有し、残部がAl及び不可避的不純物からなり、温度が640℃以上660℃以下の範囲内にある溶融金属浴に前記鋼板を浸漬した後、610℃から500℃までの平均冷却速度を10℃/s以上として急速冷却を施すステップを含むことを特徴とする。 The method for producing a molten Al-Si-based plated steel sheet according to the present invention is a method for producing a molten Al-Si-based plated steel sheet according to the present invention, all of which have an atomic% concentration of Si: 1% or more and 13% or less, Fe. : 2% or less, Cu: 0.05% or more and 3% or less, one or more elements selected from Mg, Ca, Ti, Mn, Zn are contained within a total range of 10% or less, and the balance is Al. After immersing the steel sheet in a molten metal bath whose temperature is in the range of 640 ° C or higher and 660 ° C or lower, the steel plate is rapidly cooled with an average cooling rate of 10 ° C / s or higher from 610 ° C to 500 ° C. It is characterized by including a step of applying.
本発明によれば、化成処理性を向上可能な溶融Al-Si系めっき鋼板及びその製造方法を提供することができる。 According to the present invention, it is possible to provide a molten Al—Si-based plated steel sheet capable of improving chemical conversion processability and a method for producing the same.
以下、本発明に係る溶融Al-Si系めっき鋼板及びその製造方法について説明する。なお、以下の説明において、めっき層及びめっき浴の組成を示す各元素の含有量の単位はいずれも「原子%濃度(at%)」であり、以下、特に断らない限り単に「%」で示す。 Hereinafter, the molten Al—Si-based plated steel sheet according to the present invention and a method for producing the same will be described. In the following description, the unit of the content of each element indicating the composition of the plating layer and the plating bath is "atomic% concentration (at%)", and hereinafter, unless otherwise specified, it is simply indicated by "%". ..
〔溶融Al-Siめっき鋼板の構成〕
まず、本発明に係る溶融Al-Si系めっき鋼板の構成について説明する。
[Structure of hot-dip Al-Si plated steel sheet]
First, the configuration of the molten Al—Si-based plated steel sheet according to the present invention will be described.
本発明に係る溶融Al-Si系めっき鋼板は、鋼板と、鋼板の表面に形成された、少なくともAl,Si,及びFeを含有する界面合金層と、界面合金層の表面に形成された、少なくともAl,Si,及びCuを含有するめっき層と、を有している。 The molten Al-Si-based plated steel sheet according to the present invention includes a steel sheet, an interfacial alloy layer containing at least Al, Si, and Fe formed on the surface of the steel sheet, and at least formed on the surface of the interfacial alloy layer. It has a plating layer containing Al, Si, and Cu.
めっき層のSi含有率は1%以上13%以下の範囲内にある。Si含有率が1%未満である場合、Fe−Al界面合金層の成長を抑制できない。一方、Si含有率が13%超である場合には、Fe−Al界面合金層の成長を抑制する効果が飽和する。 The Si content of the plating layer is in the range of 1% or more and 13% or less. When the Si content is less than 1%, the growth of the Fe—Al interfacial alloy layer cannot be suppressed. On the other hand, when the Si content is more than 13%, the effect of suppressing the growth of the Fe—Al interfacial alloy layer is saturated.
めっき層のCu含有率は0.05%以上3%以下の範囲内にある。Cuをめっき層に含有することで、化成処理時にめっき層の表面に電位勾配が生じ、局所的にpHが上昇し化成結晶の生成を促進できる。Cu含有率が0.05%未満である場合、十分な化成処理性改善効果が得られない。一方、Cu含有率が3%超である場合には、Al2Cu相の析出量が急激に増加し、耐食性が低下する。 The Cu content of the plating layer is in the range of 0.05% or more and 3% or less. By containing Cu in the plating layer, a potential gradient is generated on the surface of the plating layer during the chemical conversion treatment, the pH is locally increased, and the formation of chemical crystals can be promoted. When the Cu content is less than 0.05%, a sufficient effect of improving chemical conversion treatment property cannot be obtained. On the other hand, when the Cu content is more than 3%, the amount of precipitation of the Al 2 Cu phase increases sharply and the corrosion resistance decreases.
めっき層はMg,Ca,Ti,Mn,Znの中から選ばれる1種以上の元素を合計で10%以下の範囲内含有することもできる。これらの元素を含有することで、めっき層の組織が微細化し、化成処理性の改善とより優れた耐食性とを高度に両立できる。 The plating layer may contain one or more elements selected from Mg, Ca, Ti, Mn, and Zn within a total range of 10% or less. By containing these elements, the structure of the plating layer becomes finer, and it is possible to achieve both improvement in chemical conversion treatment property and better corrosion resistance.
X線回折で得られるAl相[111]の回折強度{I(Al)}に対するAl2Cu相[222]の回折強度{I(Al2Cu)}のメインピーク強度の比率Y=I(Al2Cu)/I(Al)は0.02以下である。比率Yが0.02超であることは、Al2Cu相がめっき層の表層に過剰に析出していることを示し、化成処理性に優れた合金組成であっても耐食性に劣った皮膜となる可能性がある。比率Yと製造パラメータの相関は明らかでないが、浴中Cu量の増大及びめっき後の冷却速度の低下により増大する傾向にある。 Ratio of main peak intensity of Al 2 Cu phase [222] diffraction intensity {I (Al 2 Cu)} to Al phase [111] diffraction intensity {I (Al)} obtained by X-ray diffraction Y = I (Al) 2 Cu) / I (Al) is 0.02 or less. When the ratio Y is more than 0.02, it means that the Al 2 Cu phase is excessively precipitated on the surface layer of the plating layer, and even if the alloy composition is excellent in chemical conversion treatment, the film is inferior in corrosion resistance. There is a possibility of becoming. The correlation between the ratio Y and the production parameters is not clear, but it tends to increase due to an increase in the amount of Cu in the bath and a decrease in the cooling rate after plating.
〔溶融Al-Si系めっき鋼板の製造方法〕
本発明に係る溶融Al-Si系めっき鋼板の製造方法は、本発明に係る溶融Al-Si系めっき鋼板を製造する際、Si:1%以上13%以下、Fe:2%以下、Cu:0.05%以上3%以下、Mg,Ca,Ti,Mn,Znの中から選ばれる1種以上の元素を合計で10%以下の範囲内含有し、残部がAl及び不可避的不純物からなり、温度が640℃以上660℃以下の範囲内にある溶融金属浴に鋼板を浸漬した後、鋼板を取り出し、610℃から500℃までの平均冷却速度を10℃/s以上として急速冷却を施すステップを含む。
[Manufacturing method of molten Al-Si plated steel sheet]
The method for producing a hot-dip Al-Si-based plated steel sheet according to the present invention is that when the hot-dip Al-Si-based plated steel sheet according to the present invention is manufactured, Si: 1% or more and 13% or less, Fe: 2% or less, Cu: 0. It contains .05% or more and 3% or less, one or more elements selected from Mg, Ca, Ti, Mn, and Zn within a total range of 10% or less, and the balance consists of Al and unavoidable impurities, and the temperature. Includes a step of immersing the steel sheet in a molten metal bath in the range of 640 ° C. or higher and 660 ° C. or lower, taking out the steel sheet, and rapidly cooling the steel sheet at an average cooling rate of 10 ° C./s or higher from 610 ° C. to 500 ° C. ..
次に、本発明の実施例について説明する。 Next, examples of the present invention will be described.
(サンプル1〜43)
サンプルとなる全ての溶融Al-Si系めっき鋼板について、常法で製造した板厚0.8mmの冷延鋼板を下地鋼板として用い、溶融めっき設備において、めっき浴の浴温を660℃、鋼板の浸入温度を680℃、ラインスピード60mpm、浸漬時間2秒で、めっき浴の組成を種々の条件に変化させ、各サンプルの溶融Al-Si系めっき鋼板を製造した。なお、めっき浴の組成は、サンプルの製造に用いためっき浴から約2gを採取し、化学分析によって確認した。各サンプルのめっき浴の組成を以下の表1に示す。また、めっき浴浸漬後の窒素ガスによる冷却の610℃から500℃までの冷却速度を以下の表1に示す。さらに、界面合金層及びめっき層の組成については、各サンプルの溶融Al-Si系めっき鋼板から任意の3断面を剪断加工により切り出し、カーボン樹脂に埋め込んだ上でSEM−EDX観察を行い、界面合金層及びめっき層のうち、任意の5点でEDXにより測定した半定量分析値の平均値を用いた。各サンプルの界面合金層及びめっき層の組成を以下の表1に示す。
(Samples 1-43)
For all of the molten Al-Si based plated steel sheet as a sample, using a cold-rolled steel sheet having a thickness of 0.8mm was prepared in a conventional manner as a substrate steel sheet in hot dipping equipment, bath temperature to 660 ° C. of the plating bath, the steel sheet The composition of the plating bath was changed under various conditions at a penetration temperature of 680 ° C., a line speed of 60 mpm, and a immersion time of 2 seconds to produce molten Al-Si-based plated steel sheets for each sample. The composition of the plating bath was confirmed by chemical analysis by collecting about 2 g from the plating bath used for producing the sample. The composition of the plating bath of each sample is shown in Table 1 below. The cooling rates of cooling with nitrogen gas after immersion in the plating bath from 610 ° C to 500 ° C are shown in Table 1 below. Furthermore, regarding the composition of the interfacial alloy layer and the plating layer, any three cross sections are cut out from the molten Al-Si-based plated steel plate of each sample by shearing, embedded in carbon resin, and then SEM-EDX observation is performed to perform interfacial alloy. Of the layer and the plating layer, the average value of the semi-quantitative analysis values measured by EDX at any 5 points was used. The composition of the interfacial alloy layer and the plating layer of each sample is shown in Table 1 below.
各サンプルの溶融Al-Si系めっき鋼板の比率Y、化成処理性、裸耐食性、及び塗装後耐食性を以下に示す方法により評価した。 The ratio Y of the molten Al—Si plated steel sheet of each sample, chemical conversion treatment property, bare corrosion resistance, and corrosion resistance after painting were evaluated by the methods shown below.
1.比率Y
Al相[111]の回折強度{I(Al)}に対するAl2Cu相[222]の回折強度{I(Al2Cu)}のメインピーク強度の比率Y=I(Al2Cu)/I(Al)は、Cu−Kα線を使用したX線回折装置により回折図形を測定して判定した。
1. 1. Ratio Y
Ratio of main peak intensity of Al 2 Cu phase [222] diffraction intensity {I (Al 2 Cu)} to Al phase [111] diffraction intensity {I (Al)} Y = I (Al 2 Cu) / I ( Al) was determined by measuring the diffraction pattern with an X-ray diffractometer using Cu—Kα rays.
2.化成処理性
市販の化成処理薬剤(日本パーカライジング株式会社製パルボンドSX−35)を用いて、浴温:35℃、フリーフッ素濃度:200質量ppm、処理時間:120秒の条件で鋼板の化成処理を行った後、そのめっき鋼板の表面を走査型電子顕微鏡にて1000倍で10視野観察した。結晶の形態については、面積率98%以上の均一な化成結晶が10視野全てにおいて生成しているものを優(◎)、面積率98%未満の視野が1視野認められるものを良(○)、面積率98%未満の視野が2視野認められるものを可(△)とし、面積率98%未満の視野が3視野以上認められるものを不可(×)として評価した。なお、ここでいう隙間とは、均一な化成結晶が生成していない箇所のことを指し、反射電子像を2値化することにより空隙の面積率を算出した。また、結晶の付着量は、化成処理試験後の試料3点を20g/Lの重クロム酸アンモニウム水溶液に15分間浸漬し、浸漬前後の重量差から試験片面積当たりの値として算出した。3点すべてにおいて結晶の付着量が2.0g/m2以上のものを優(◎)、1.8g/m2以上2.0g/m2未満のものを良(○)、1.5g/m2以上1.8g/m2未満のものを可(△)、1.5g/m2未満のものが1点でも認められるものを不可(×)として評価した。
2. Chemical conversion treatment Using a commercially available chemical conversion treatment agent (Palbond SX-35 manufactured by Nippon Parkering Co., Ltd.), chemical conversion treatment of a steel sheet is performed under the conditions of a bath temperature of 35 ° C., a free fluorine concentration of 200 mass ppm, and a treatment time of 120 seconds. After that, the surface of the plated steel sheet was observed with a scanning electron microscope at 1000 times for 10 fields. Regarding the crystal morphology, those in which uniform chemical crystals having an area ratio of 98% or more are formed in all 10 visual fields are excellent (◎), and those in which one visual field with an area ratio of less than 98% is recognized are good (○). Those having two visual fields with an area ratio of less than 98% were evaluated as acceptable (Δ), and those having three or more visual fields with an area ratio of less than 98% were evaluated as unacceptable (x). The gap referred to here refers to a place where uniform chemical crystals are not formed, and the area ratio of the gap was calculated by binarizing the reflected electron image. The amount of crystals adhered was calculated as a value per test piece area from the weight difference before and after immersion in 3 points of the sample after the chemical conversion treatment test in a 20 g / L ammonium dichromate aqueous solution for 15 minutes. At all three points, those with a crystal adhesion amount of 2.0 g / m 2 or more are excellent (◎), those with a crystal adhesion amount of 1.8 g / m 2 or more and less than 2.0 g / m 2 are good (○), 1.5 g / m. Those having m 2 or more and less than 1.8 g / m 2 were evaluated as acceptable (Δ), and those having less than 1.5 g / m 2 were evaluated as unacceptable (×).
3.裸耐食性
各サンプルの溶融Al-Si系めっき鋼板について、JIS Z2371−2000に準拠した塩水噴霧試験を行った。各サンプルの赤錆が発生するまでの時間を測定し、以下の基準により裸耐食性を評価した。評価結果を以下の表1に示す。
3. 3. Bare Corrosion Resistance The molten Al-Si galvanized steel sheets of each sample were subjected to a salt spray test in accordance with JIS Z2371-2000. The time until red rust occurred in each sample was measured, and the bare corrosion resistance was evaluated according to the following criteria. The evaluation results are shown in Table 1 below.
◎:赤錆発生時間≧600時間
○:300時間≦赤錆発生時間<600時間
△:150時間≦赤錆発生時間<300時間
×:赤錆発生時間<150時間
⊚: Red rust occurrence time ≥ 600 hours ○: 300 hours ≤ Red rust occurrence time <600 hours Δ: 150 hours ≤ Red rust occurrence time <300 hours ×: Red rust occurrence time <150 hours
4.塗装後耐食性
各サンプルの溶融Al-Si系めっき鋼板について、それぞれ70mm×80mmのサイズに剪断後、自動車外板用塗装処理と同様に、化成処理としてリン酸亜鉛処理を行った後、電着塗装を施した。ここで、リン酸亜鉛処理及び電着塗装は、以下の条件で行った。
4. Corrosion resistance after painting Each sample of molten Al-Si plated steel sheet is sheared to a size of 70 mm x 80 mm, and then subjected to zinc phosphate treatment as a chemical conversion treatment in the same manner as the painting treatment for automobile outer panels, and then electrodeposition coating. Was given. Here, the zinc phosphate treatment and electrodeposition coating were performed under the following conditions.
リン酸亜鉛処理:市販の化成処理薬剤(日本パーカライジング株式会社製パルボンドSX−35)を用いて、浴温:35℃、フリーフッ素濃度:200質量ppm、処理時間:120秒の条件で溶融Al-Si系めっき鋼板の化成処理を行った。 Zinc phosphate treatment: Using a commercially available chemical conversion treatment agent (Palbond SX-35 manufactured by Nippon Parkering Co., Ltd.), molten Al-under the conditions of bath temperature: 35 ° C., free fluorine concentration: 200 mass ppm, and treatment time: 120 seconds. A chemical conversion treatment was performed on a Si-based plated steel sheet.
電着塗装:関西ペイント社製の電着塗料:GT−100を用いて、膜厚が15μmとなるように電圧を調整して電着塗装を施した。 Electrodeposition coating: Using an electrodeposition coating material manufactured by Kansai Paint Co., Ltd .: GT-100, electrodeposition coating was performed by adjusting the voltage so that the film thickness was 15 μm.
化成処理及び電着塗装後、評価面の端部7.5及び非評価面(背面)をテープでシール処理を行った後、評価面の中央にカッターナイフで溶融Al-Si系めっき鋼板の地鉄に到達する深さまで、長さ60mm、中心角60°のクロスカット傷を加えたものを、塗装後耐食性の評価用サンプルとして用いた。 After chemical conversion treatment and electrodeposition coating, the edge 7.5 of the evaluation surface and the non-evaluation surface (back surface) are sealed with tape, and then the base of the molten Al-Si galvanized steel sheet is placed in the center of the evaluation surface with a cutter knife. A cross-cut scratch with a length of 60 mm and a central angle of 60 ° to a depth reaching iron was used as a sample for evaluation of corrosion resistance after painting.
上記評価用サンプルを用いて、SAE J2334に規定されたサイクルで腐食促進試験を実施した。腐食促進試験を湿潤状態からスタートし、60サイクル後まで行った後、傷部からの塗膜膨れが最大である部分の塗膜膨れ幅(最大塗膜膨れ幅:傷部を中央にした片側の最大塗膜膨れ幅)を測定し、塗装後耐食性を以下の基準で評価した。評価結果を以下の表1に示す。 Using the above evaluation sample, a corrosion acceleration test was carried out in the cycle specified in SAE J2334. After starting the corrosion acceleration test from a wet state and performing it up to 60 cycles later, the coating film swelling width of the part where the coating film swelling from the scratched part is the maximum (maximum coating film swelling width: one side with the scratched part in the center) The maximum coating film swelling width) was measured, and the corrosion resistance after coating was evaluated according to the following criteria. The evaluation results are shown in Table 1 below.
◎:最大塗膜膨れ幅≦2.0mm
○:2.0mm<最大塗膜膨れ幅≦3.0mm
△:3.0mm<最大塗膜膨れ幅≦4.0mm
×:最大塗膜膨れ幅>4.0mm
⊚: Maximum coating film swelling width ≤ 2.0 mm
◯: 2.0 mm <maximum coating film swelling width ≤ 3.0 mm
Δ: 3.0 mm <maximum coating film swelling width ≤ 4.0 mm
X: Maximum coating film swelling width> 4.0 mm
以下の表1に示すように、比較例では化成処理性が不足しているか、あるいはAl2Cu相が過剰となりいずれも塗装後耐食性に不足があった。これに対して、本発明例は化成処理性及び塗装後耐食性共に優れていた。これにより、本発明によれば、溶融Al−Si系めっき鋼板の化成処理性を向上させることにより塗装後耐食性を改善できることが確認された。 As shown in Table 1 below, in the comparative examples, the chemical conversion treatment property was insufficient, or the Al 2 Cu phase was excessive, and the corrosion resistance after coating was insufficient in both cases. On the other hand, the example of the present invention was excellent in both chemical conversion treatment property and corrosion resistance after painting. As a result, according to the present invention, it was confirmed that the corrosion resistance after coating can be improved by improving the chemical conversion treatment property of the molten Al—Si-based plated steel sheet.
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