Welded joints and automotive parts

By designing a specific coating structure and Zn intrusion part in the welded joint, the problems of liquid metal embrittlement and cracking and insufficient corrosion resistance during spot welding of coated steel plates are solved, achieving both LME crack suppression and corrosion resistance improvement in high-strength steel plates.

CN116685699BActive Publication Date: 2026-07-03NIPPON STEEL CORPORATION

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NIPPON STEEL CORPORATION
Filing Date
2021-12-24
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

In the existing technology, spot welding of coated steel sheets is prone to liquid metal embrittlement (LME) and insufficient corrosion resistance of the welded joint, failing to effectively address both issues.

Method used

Design a welded joint structure in which one steel plate has a coating on its surface and the other steel plate has no coating or different coatings on its surface. The spot weld has a weld nugget and a plastic metal ring region. A Zn intrusion region exists within the boundary coating range. The Zn intrusion region progresses along the steel grain boundary. The Mg/Zn ratio of the coating satisfies a specific relationship to ensure the corrosion resistance and LME cracking inhibition of the welded joint.

Benefits of technology

It effectively inhibits the embrittlement and cracking of liquid metal and improves the corrosion resistance of welded joints, especially showing significant effects in the application of high-strength steel plates.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN116685699B_ABST
    Figure CN116685699B_ABST
Patent Text Reader

Abstract

The present disclosure provides a technique for suppressing liquid metal embrittlement (LME) cracking and improving corrosion resistance in a welded joint obtained by spot welding a first steel plate and a second steel plate. In the welded joint of this disclosure, a first coating is provided on the surface of the first steel plate opposite to the second steel plate, and a second coating is either absent or present on the surface of the second steel plate opposite to the first steel plate. A boundary coating is provided between the first and second steel plates, extending 0.5 mm outward from the end of the plastic metal ring region of the spot weld. A Zn intrusion portion is present in at least one of the first and second steel plates adjacent to the boundary coating. The Zn intrusion portion progresses along the steel grain boundary from the boundary coating, and the Mg concentration at the leading edge of the Zn intrusion portion and at a location where the Zn concentration is 0.1% by mass is 0.20% by mass or less. The first and second coatings satisfy a predetermined relationship I.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application discloses welded joints and automotive parts. Background Technology

[0002] When multiple coated steel sheets are joined by spot welding, metallic components in the coating may penetrate into the grain boundaries of the steel sheets, causing liquid metal embrittlement (LME) cracking. LME cracking is particularly problematic in high-strength steel sheets.

[0003] As a technique to suppress LME cracking during spot welding, Patent Document 1 discloses a technique that determines the post-weld holding time of the welding electrode based on a function of the total plate thickness during spot welding. Furthermore, although not directly related to LME cracking, Patent Document 2 discloses a technique that applies ultrasonic impact treatment to the spot weld area to open cracks in the weld area and inhibit the intrusion of moisture into the cracks.

[0004] Existing technical documents

[0005] Patent documents

[0006] Patent Document 1: Japanese Patent Application Publication No. 2017-047045

[0007] Patent Document 2: Japanese Patent Application Publication No. 2005-103608 Summary of the Invention

[0008] The problem that the invention aims to solve

[0009] In previous technologies, LME cracking was suppressed through the processes and operations involved in spot welding. However, there has been insufficient research on suppressing LME cracking by focusing on the cladding steel itself. In this respect, there is room for improvement in suppressing LME cracking in welded joints.

[0010] Furthermore, previous techniques have not adequately addressed ensuring the corrosion resistance of welded joints. In this regard, there is room for improvement in achieving both LME crack suppression and corrosion resistance in welded joints.

[0011] Methods for solving problems

[0012] As one means of solving the above-mentioned problems, this application discloses a welded joint comprising a first steel plate, a second steel plate, and a spot weld portion for joining the first steel plate and the second steel plate.

[0013] On the surface of the first steel plate opposite to the second steel plate, a first coating is provided.

[0014] On the surface of the second steel plate opposite to the first steel plate, there is either no coating or a second coating.

[0015] The aforementioned spot weld has a weld nugget and a corona bond.

[0016] A boundary plating layer is provided between the first steel plate and the second steel plate, and within a range of 0.5 mm from the end of the plastic metal ring region toward the outer side of the spot weld.

[0017] In at least one of the first steel plate and the second steel plate adjacent to the aforementioned boundary coating, there is a Zn intrusion portion.

[0018] The aforementioned Zn intrusion portion progresses along the steel grain boundary from the aforementioned boundary coating.

[0019] The Mg concentration at the tip of the Zn intrusion site, where the Zn concentration is 0.1% by mass, is less than 0.20% by mass.

[0020] The first coating and the second coating satisfy the following relationship I.

[0021] Relationship I: 0.010 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)] 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0022] In the absence of the aforementioned second coating, the Mg composition, Zn composition, and adhesion amount of the second coating are all 0.

[0023] In the welded joint of this disclosure, the first coating and the second coating can also satisfy the following relationship I-1.

[0024] Relationship I-1: 0.006 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)) 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0025] In the welded joints disclosed herein, one or more oxides with a major diameter of 0.5 μm or more may be present in the aforementioned boundary coating.

[0026] The welded joint of this disclosure may also have an internal oxide layer with a depth of 1.5 μm to 20.0 μm on one side of the first steel plate opposite to the second steel plate.

[0027] In the welded joint disclosed herein, the tensile strength of the steel plate having the Zn intrusion portion in the first steel plate and the second steel plate may also be 590 MPa or higher.

[0028] The welded joint disclosed herein can be used, for example, as an automotive component. For instance, an automotive component of this disclosure may also include the aforementioned welded joint, wherein the first steel plate is disposed on the outer side of the vehicle, the second steel plate is disposed on the inner side of the vehicle, and the second coating has a lower Mg composition than the first coating.

[0029] In the automotive parts disclosed herein, the ratio of [Mg composition (mass %) of the first coating layer] to [Zn composition (mass %) of the first coating layer] may also be greater than 0.01.

[0030] Invention Effects

[0031] In the welded joints disclosed herein, it is easy to balance the suppression of LME cracking and the assurance of corrosion resistance. Attached Figure Description

[0032] Figure 1 Here is a rough example of the cross-sectional structure of a welded joint.

[0033] Figure 2 This is a rough example of the cross-sectional structure of the Zn intrusion.

[0034] Figure 3 An example of the cross-sectional structure of the Zn intrusion portion.

[0035] Figure 4 An example that roughly illustrates the composition of a car component. Detailed Implementation

[0036] 1. Welded joint

[0037] like Figures 1-3As shown, the welded joint 100 includes a first steel plate 10, a second steel plate 20, and a spot weld portion 30 that joins the first steel plate 10 and the second steel plate 20. A first plating layer 11 is provided on the surface of the first steel plate 10 opposite to the second steel plate 20. On the surface of the second steel plate 20 opposite to the first steel plate 10, there is no plating layer or a second plating layer 21 is provided. The spot weld portion 30 includes a weld nugget 31 and a plastic metal ring region 32. A boundary plating layer 50 is provided between the first steel plate 10 and the second steel plate 20, extending 0.5 mm outward from the end of the plastic metal ring region 32 toward the spot weld portion 30. A Zn intrusion portion 60 is present in at least one of the first steel plate 10 and the second steel plate 20 adjacent to the boundary plating layer 50, and the Zn intrusion portion 60 progresses along the steel grain boundary from the boundary plating layer. With regard to the welded joint 100, the Mg concentration at the front end of the Zn intrusion portion and the portion where the Zn concentration is 0.1% by mass is 0.20% by mass or less, and the first coating and the second coating satisfy the following relationship I.

[0038] Relationship I: 0.010 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)] 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0039] In the absence of the aforementioned second coating, the Mg composition, Zn composition, and adhesion amount of the second coating are all 0.

[0040] 1.1 Steel Plate

[0041] The first steel plate 10 and the second steel plate 20 can be steel plates with low tensile strength or steel plates with high tensile strength, but a high LME cracking suppression effect can be expected, especially when at least one of the first steel plate 10 and the second steel plate 20 is a high-strength steel plate with high tensile strength. For example, in the welded joint 100, at least one of the first steel plate 10 and the second steel plate 20 can also have a tensile strength of 590 MPa or more. That is, in the welded joint 100, the tensile strength of the first steel plate 10 can be 590 MPa or more and the tensile strength of the second steel plate 20 can be less than 590 MPa, or the tensile strength of the first steel plate 10 can be less than 590 MPa and the tensile strength of the second steel plate 20 can be 590 MPa or more, or both the first steel plate 10 and the second steel plate 20 can have a tensile strength of 590 MPa or more. The first steel plate 10 and the second steel plate 20 may have the same or different tensile strengths. Furthermore, in the welded joint 100, at least one of the first steel plate 10 and the second steel plate 20 may have a tensile strength of 780 MPa or more, 980 MPa or more, 1180 MPa or more, or 1470 MPa or more. Additionally, in the welded joint 100, the tensile strength of the steel plate having the Zn intrusion portion 60 (described later) in the first steel plate 10 and the second steel plate 20 may be 590 MPa or more, 780 MPa or more, 980 MPa or more, 1180 MPa or more, or 1470 MPa or more. There is no particular upper limit to the tensile strength; for example, it may be 2500 MPa or less, 2200 MPa or less, or 2000 MPa or less. It should be noted that the "tensile strength" of the steel plate referred to in this application is based on the tensile strength of ISO 6892-1:2009.

[0042] The effects of the welded joint 100 of this disclosure can be achieved regardless of the chemical composition and microstructure of the first steel plate 10 and the second steel plate 20. The chemical composition and microstructure of the steel plates 10 and 20 can be appropriately determined according to the application of the welded joint 100. For example, the first steel plate 10 and the second steel plate 20 may have the following chemical composition: containing, by mass %: C: 0.01–0.50%, Si: 0.01–3.50%, Mn: 0.10–5.00%, P: 0.100% or less, S: 0.0300% or less, N: 0.0100% or less, O: 0–0.020%, Al: 0–1.000%, B: 0–0.010%, Nb: 0–0.150%, Ti: 0–0.20%, Mo: 0–3.00%, Cr The composition of the chemical composition is as follows: 0–2.00% V, 0–1.00% Ni, 0–2.00% W, 0–1.00% Ta, 0–0.10% Co, 0–3.00% Sn, 0–1.00% Sb, 0–0.50% Cu, 0–2.00% As, 0–0.050% Mg, 0–0.100% Ca, 0–0.100% Zr, 0–0.100% Hf, and 0–0.100% REM, with the remainder consisting of Fe and impurities. Furthermore, in the above chemical composition, the lower limit of the content of optionally added elements can also be 0.0001% or 0.001%.

[0043] There is no particular limitation on the thickness of the first steel plate 10 and the second steel plate 20. The plate thickness can be determined appropriately according to the application. For example, the plate thickness can be 0.5 mm or more, 0.8 mm or more, 1.0 mm or more, 1.2 mm or more, or 2.0 mm or more, and can also be less than 10.0 mm, 5.0 mm or less, 4.0 mm or less, or 3.0 mm or less. The plate thickness can be the same throughout the steel plate or it can vary in different parts of the steel plate.

[0044] 1.2 Coating

[0045] In the welded joint 100, a first plating layer 11 is provided on the surface of the first steel plate 10 opposite to the second steel plate 20. Furthermore, on the surface of the second steel plate 20 opposite to the first steel plate 10, there is either no plating layer or a second plating layer 21 is provided. Figure 1The diagram shows a configuration with both a first coating 11 and a second coating 21, but the configuration of the coating in the welded joint 100 is not limited to this. In the welded joint 100, the first steel plate 10 and the second steel plate 20 can be welded together with the coating sandwiched between them. It should be noted that the surface of the first steel plate 10 that is not opposite to the second steel plate 20 may or may not have a coating. Similarly, the surface of the second steel plate 20 that is not opposite to the first steel plate 10 may or may not have a coating. The first coating 11 and the second coating 21 may be of the same type or different types. The chemical composition of the first coating 11 and the second coating 21 is not particularly limited as long as it satisfies Relation I described later and meets the specified Mg concentration in the front end 60a of the Zn intrusion portion 60. The first coating 11 and the second coating 21 may be Zn-based coatings, and for example, may have the following chemical compositions.

[0046] (A1: 0-90.0%)

[0047] By including Al in the coating, it is possible to improve the corrosion resistance of the coating. The Al content in each of the first coating 11 and the second coating 21, in terms of mass%, can be 0%, or 0.010% or more, 0.100% or more, 0.500% or more, 1.0% or more, or 3.0% or more. Furthermore, the Al content in each of the first coating 11 and the second coating 21, in terms of mass%, can be 90.0% or less, 80.0% or less, 70.0% or less, 60.0% or less, 50.0% or less, 40.0% or less, 30.0% or less, 20.0% or less, 10.0% or less, or 5.0% or less. In the welded joint 100, one or both of the first coating 11 and the second coating 21 may be free of Al, or one or both of the first coating 11 and the second coating 21 may contain Al.

[0048] (Mg: 0-60.0%)

[0049] By including Mg in the coating, it is possible to improve the corrosion resistance of the coating. The Mg content in each of the first coating 11 and the second coating 21, in mass %, can be 0%, or 0.010% or more, 0.100% or more, 0.500% or more, 1.0% or more, or 3.0% or more. Furthermore, the Mg content in each of the first coating 11 and the second coating 21, in mass %, can be 60.0% or less, 50.0% or less, 40.0% or less, 30.0% or less, 20.0% or less, 10.0% or less, or 5.0% or less. However, as is self-evident from relation I, at least one of the first coating 11 and the second coating 21 contains Mg. The Mg content in the Mg-containing coatings of the first coating 11 and the second coating 21 can be, for example, 0.100% or more, 0.500% or more, 0.800% or more, or 1.0% or more by mass%, or it can be less than 60.0%, less than 40.0%, less than 20.0%, or less than 5.0%. In the welded joint 100, one of the first coating 11 and the second coating 21 may be Mg-free, or either or both of the first coating 11 and the second coating steel plate 21 may contain Mg.

[0050] (Fe: 0–65.0%)

[0051] When heat treatment is performed after a coating is formed on the surface of a steel sheet, Fe may diffuse from the steel sheet into the coating. The Fe content in each of the first coating 11 and the second coating 21, by mass%, can be 0%, or 1.0% or more, 2.0% or more, 3.0% or more, 4.0% or more, or 5.0% or more. Furthermore, the Fe content in each of the first coating 11 and the second coating 21, by mass%, can be 65.0% or less, 55.0% or less, 45.0% or less, 35.0% or less, 25.0% or less, 15.0% or less, 12.0% or less, 10.0% or less, 8.0% or less, or 6.0% or less.

[0052] (Si: 0~10.0%)

[0053] By including Si in the coating, it is possible to improve the corrosion resistance of the coating. The Si content in each of the first coating 11 and the second coating 21, in terms of mass%, can be 0%, or 0.005% or more, 0.010% or more, 0.050% or more, or 0.100% or more. Furthermore, the Si content in each of the first coating 11 and the second coating 21, in terms of mass%, can be 10.0% or less, 8.0% or less, 5.0% or less, 3.0% or less, 2.5% or less, 2.0% or less, 1.5% or less, or 1.0% or less.

[0054] (other)

[0055] The first coating 11 and the second coating 21 may each optionally contain, by mass percent, one or more of the following: Sb: 0-0.50%, Pb: 0-0.50%, Cu: 0-1.0%, Sn: 0-1.0%, Ti: 0-1.0%, Sr: 0-0.50%, Cr: 0-1.0%, Ni: 0-1.0%, and Mn: 0-1.0%. The total content of these optional added elements may, for example, be less than 5.0% or less than 2.0%.

[0056] The remaining components in the first coating 11 and the second coating 21, other than those described above, may consist of Zn and impurities. Examples of impurities in the first coating 11 and the second coating 21 include components that may be introduced during the formation of the first coating 11 and the second coating 21 due to various reasons related to the formation process, represented by the raw materials. The first coating 11 and the second coating 21 may also contain trace amounts of elements other than those described above.

[0057] The chemical composition of the coating can be determined by dissolving the coating in an acid solution containing an inhibitor that inhibits steel corrosion, and then measuring the resulting solution using ICP (inductively coupled plasma) luminescence spectrophotometry.

[0058] The thickness of each of the first coating 11 and the second coating 21 can be, for example, 3 μm or more, or 50 μm or less. Furthermore, the adhesion amount of each of the first coating 11 and the second coating 21 is not particularly limited, but for example, it can be 10 g / m² per single side of the steel plate. 2 The above can also be 170g / m 2 The following is an explanation of the coating adhesion amount, which is determined by the weight change before and after pickling when the coating is dissolved in an acid solution containing an inhibitor that suppresses corrosion of the base metal.

[0059] (Relationship I)

[0060] In the welded joint 100, the first plating layer 11 and the second plating layer 21 satisfy the following relationship I. In other words, the average Mg / Zn obtained by weighting the composition contained in the first plating layer 11 and the second plating layer 21 considering the amount of plating adhered satisfies the following relationship I. It should be noted that in this disclosure, when referring to "average" in relation to chemical composition, it refers to this weighted average.

[0061] Relationship I: 0.010 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)] 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m))2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0062] The aforementioned Relationship I refers to the mass ratio of Mg to Zn (average Mg / Zn) in the welded joint 100, where the chemical composition of the first coating 11 and the second coating 21 are averaged, being between 0.001 and 0.010. By maintaining an average Mg / Zn within this range, superior LME cracking inhibition and corrosion resistance can be ensured. The lower limit of Relationship I can also be 0.002 or higher, or 0.003 or higher. The upper limit can also be 0.009 or lower, 0.008 or lower, 0.007 or lower, 0.006 or lower, or 0.005 or lower. In particular, even higher LME cracking inhibition and corrosion resistance can be expected when the first coating 11 and the second coating 21 satisfy Relationship I-1.

[0063] Relationship I-1: 0.006 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)) 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0064] Furthermore, as described above, the second plating layer 21 may also be absent in the welded joint 100. That is, in relation I above, when the second plating layer 21 is absent, the Mg composition, Zn composition, and adhesion amount of the second plating layer 21 are 0.

[0065] Whether the above relationship I is satisfied in the welded joint 100 can be determined by measuring the chemical composition and adhesion amount of the first plating layer 11 and the second plating layer 21 of the welded joint 100. The chemical composition and adhesion amount of the first plating layer 11 and the second plating layer 21 can be confirmed, for example, only in the portions of plating layers 11 and 21 that are sufficiently far away from the spot weld portion 30.

[0066] 1.3 Spot weld section

[0067] In the welded joint 100, the first steel plate 10 and the second steel plate 20 are joined by a spot weld 30. For example... Figure 1As shown, if the first steel plate 10 and the second steel plate 20 are spot welded, a portion of the steel composition and / or coating composition, referred to as a melt nugget 31, is formed at the part where pressure is applied through the electrodes. Then, a plastic metal ring region 32, where the aforementioned components are joined without melting, is formed around the melt nugget 31. It should be noted that the "plastic metal ring region" refers to the area where the first and second steel plates are pressure-welded around the melt nugget. The coating at the portion normally located in the plastic metal ring region is extruded to the periphery of the plastic metal ring region during its formation. Sometimes, Zn may remain in the plastic metal ring region. In this case, Zn remains in a state of solid solution in the first and second steel plates. Even with solid solution Zn, the first and second steel plates are in contact without gaps in the plastic metal ring region, thus allowing identification of the end of the plastic metal ring region. Furthermore, the Zn intrusion portion described later is not formed by solid solution Zn in the plastic metal ring region. This is because the Zn in solid solution exists as the α-(Fe,Zn) phase even at high temperatures and does not precipitate. The melt nugget 31 and the ductile metal ring region 32, due to their different chemical compositions, can be easily distinguished, for example, by using a scanning electron microscope (SEM) with reflected electron images (BSE images). There are no particular limitations on the shape and composition of the melt nugget 31 in the welded joint 100.

[0068] 1.4 Separation Section

[0069] In the welded joint 100, a separation portion 40 exists around the spot weld portion 30 (around the ductile metal ring region 32). The separation portion 40 refers to the portion where no spot welding or pressure welding occurs. That is, the "separation portion" refers to the area around the ductile metal ring region where the first steel plate and the second steel plate are not in direct contact. For example... Figure 1 As shown, in the separation section 40 surrounding the spot weld section 30, no welding or pressure welding is performed between the first steel plate 10 and the second steel plate 20, and a gap may exist between the first steel plate 10 and the second steel plate 20. The size of the gap in the separation section 40 is not particularly limited.

[0070] 1.5 Boundary Coating

[0071] "Boundary coating" refers to the coating obtained by melting and solidifying around the plastic metal ring region through welding heat input. The boundary coating is also called the boundary portion. In the welded joint 100, the boundary coating 50 is contained within a range of 0.5 mm from the end of the plastic metal ring region 32 towards the outside of the spot weld portion 30. That is, the coating within the range of 0.5 mm from the end of the plastic metal ring region 32 towards the outside of the spot weld portion 30 of the coatings 11 and 21 present on the opposing surfaces of the first steel plate 10 and the second steel plate 20 becomes the boundary coating 50 through spot welding. Furthermore, the coating at the location of the plastic metal ring region 32 is squeezed out to the outside of the plastic metal ring region during spot welding to form part of the boundary coating 50. The higher the welding heat input of the spot weld, the further the range becoming the boundary coating 50 expands towards the outside of the spot weld. Furthermore, if there is no coating on the surface of the second steel plate 20 opposite to the first steel plate 10, it is possible that the coating of the first steel plate melts and wraps back to the side of the second steel plate 20 adjacent to the separation portion 40 of the plastic metal ring region 32, forming a boundary coating 50. The boundary coating 50 is as follows... Figure 1 As shown, it can have a fan-shaped (semi-circular) cross-sectional shape, or other shapes. The shape of the boundary plating 50 can vary depending on the spot welding conditions, etc.

[0072] In the welded joint 100, the boundary coating 50 contains components derived from the first coating 11 and the second coating 21. That is, the boundary coating 50 can be formed by solidifying the coatings 11, 21, etc., which are fused by spot welding. For example, when both the first coating 11 and the second coating 21 are present, the components derived from these two coatings 11, 21 are mixed with components derived from the steel plate in the boundary coating 50. That is, in addition to the components derived from the first coating 11 and the second coating 21, components derived from the steel plates 10 and 20 may also be present in the boundary coating 50. The chemical composition of the boundary coating 50, excluding components derived from the steel plate, can correspond to the average composition of the first coating 11 and the second coating 21 present in the welded joint 100. However, according to the inventor's understanding, the chemical composition in the boundary coating 50 fluctuates greatly, making it difficult to definitively determine the chemical composition in the boundary coating 50. In this respect, in the welded joint 100 of this disclosure, it is not necessary to determine the chemical composition of the boundary plating layer 50; it is sufficient to determine the average chemical composition of the first plating layer 11 and the second plating layer 21. That is, by satisfying the above-mentioned relation I with respect to the first plating layer 11 and the second plating layer 21, the chemical composition of the boundary plating layer 50 is likely to become a chemical composition effective in suppressing LME cracking.

[0073] As described above, the chemical composition of the boundary coating 50 is not particularly limited. The boundary coating 50 may also have the following chemical composition in at least a portion thereof. Alternatively, the boundary coating 50 may also have the following chemical composition as its average chemical composition.

[0074] (Mg / Zn: 0.001~0.010)

[0075] In the welded joint 100, the mass ratio of Mg to Zn in the boundary coating 50 (Mg / Zn) can be 0.001 to 0.010 in at least a portion of the boundary coating 50 or as the average chemical composition of the boundary coating 50. By including Mg in the boundary coating 50 in such a specified range, corrosion resistance is easily improved. The mass ratio of Mg to Zn in the boundary coating 50 (Mg / Zn) can be 0.002 or more, or 0.003 or more, or 0.009 or less, 0.008 or less, 0.007 or less, 0.006 or less, or 0.005 or less.

[0076] (Fe: less than 65.0% by mass)

[0077] The concentration of Fe in at least a portion of the boundary coating 50, or in its average chemical composition, may be 65.0% by mass or less, 55.0% by mass or less, 45.0% by mass or less, 35.0% by mass or less, 25.0% by mass or less, 15.0% by mass or less, 12.0% by mass or less, 10.0% by mass or less, 8.0% by mass or less, or 6.0% by mass or less. As described above, the boundary coating 50 is formed by the melting and mixing of metal components from coatings 11 and 21 and metal components from steel plates 10 and 20 during spot welding. That is, during spot welding, Fe can diffuse from steel plates 10 and 20 to the boundary coating 50. According to the inventor's new understanding, when the concentration of Fe coexisting with liquid Zn during spot welding is low (i.e., the diffusion of Fe from steel plates 10 and 20 to the boundary coating 50 is small), there is a tendency to suppress the intrusion of Zn into steel plates 10 and 20. To suppress the diffusion of Fe from steel plates 10 and 20 to the boundary coating 50, it is effective, for example, to perform an internal oxidation treatment, described later, on at least one of the steel plates 10 and 20. It should be noted that even if the coatings 11 and 21 before welding contain a large amount of Fe through hot stamping or the like, the concentration of Fe coexisting with the liquid Zn during welding may not necessarily increase. This is because Fe diffused into the coatings 11 and 21 through hot stamping or the like can form high-melting-point intermetallic compounds with other metals, making them difficult to melt during welding.

[0078] (Other ingredients)

[0079] In the boundary coating 50, the content of components other than those described above is not particularly limited. For example, the boundary coating 50 may contain 0.500% to 90.0% by mass of Al in at least a portion thereof or in its average chemical composition, and may also contain 0.001% to 10.0% by mass of Si. Furthermore, as described above, the boundary coating 50 may also contain other elements or impurities derived from coatings 11, 21 or steel plates 10, 20. The microstructure of the boundary coating 50 is not particularly limited.

[0080] (Oxides)

[0081] The boundary coating 50 may also have one or more oxides with a major diameter of 0.5 μm or more. That is, when observing a cross-section of the boundary coating 50, oxides with a major diameter of 0.5 μm or more may be present. Furthermore, the boundary coating 50 may have two or more, three or more, five or more, ten or more, or twenty or more oxides with a major diameter of 0.5 μm or more. Moreover, the boundary coating 50 may have two or more, three or more, five or more, ten or more, or twenty or more oxides with a major diameter of 1.5 μm or more. As described below, when at least one of the steel plates 10 and 20 undergoes internal oxidation treatment, during spot welding, the internal oxides can diffuse from the steel plates 10 and 20 to the boundary coating 50. These internal oxides can be obtained by performing a prescribed annealing treatment (including pre-annealing treatment) on the steel. In addition to oxygen, the oxide contains one or more elements from the steel plates 10 and 20, typically Si, O, and Fe, and may further contain Mn depending on the circumstances. More specifically, the oxide typically contains 5-25% Si, 0-10% Mn, 40-65% O, and 10-30% Fe. The oxide may also contain the elements mentioned above in addition to these. The oxide may also be an oxide containing Si and / or Mn. Oxides containing Si and / or Mn can promote the formation of an insulating film of corrosion products in corrosive environments. Therefore, the corrosion resistance of the weld joint 100 may be improved. It should be noted that the "major diameter" of the oxide refers to the length of the longest line segment that can be transversely cut from the oxide. The shape of the oxide is not particularly limited and may be circular, approximately circular, elliptical, polygonal, etc. The major diameter of the oxide may also be 0.7 μm or more, 1.0 μm or more, or 1.5 μm or more. There is no particular upper limit to the major axis of the oxide; for example, it can be below 10.0 μm.

[0082] 1.6Zn invasion part

[0083] like Figure 2 and 3As shown, in the welded joint 100, a Zn intrusion portion 60 is present in at least one of the first steel plate 10 and the second steel plate 20 adjacent to the boundary coating 50. The Zn intrusion portion 60 extends along the steel grain boundaries from the boundary coating 50. The Zn intrusion portion 60 can be formed by the Zn contained in the coating penetrating into the steel grain boundaries of the steel plates during spot welding. It should be noted that although the Zn intrusion portion 60 is present in the welded joint 100, it does not cause LME cracking.

[0084] The length of the Zn intrusion portion 60 along the grain boundary is not particularly limited, but it can be, for example, 0.5 μm or more, 1 μm or more, 2 μm or more, or 3 μm or more, or less than 30 μm, 15 μm or less, 10 μm or less, or 5 μm or less. The shape, intrusion direction, etc. of the Zn intrusion portion 60 can be determined according to the morphology of the grain boundary of the steel plate.

[0085] like Figure 2 As shown, the Zn penetration portion 60 may also include a first portion 61 formed by the diffusion of a liquid phase containing components from coatings 11 and 21 during spot welding, and a second portion 62 formed by the diffusion of a solid phase containing components from coatings 11 and 21 during spot welding. The first portion 61 may exist on the surface side of the steel plate closer than the second portion 62. Furthermore, as Figure 2 As shown, the Zn intrusion portion 60 has a front end portion 60a. Here, in this application, the Zn concentration is measured from the surface side of the steel plate toward the interior, along the steel grain boundaries where Zn has intruded, until the Zn concentration becomes 0.1% by mass or less. The position where the Zn concentration becomes 0.1% by mass (within the range of 0.095 to 0.104%) is considered the "front end portion 60a of the Zn intrusion portion 60", and the Mg concentration, described later, is measured. It should be noted that the main component in the front end portion 60a can be Fe.

[0086] In the Zn intrusion zone 60, the Mg concentration in the front end 60a is 0.20% by mass or less. When the Mg concentration in the front end 60a is below a specified value, it ensures that Zn is difficult to penetrate the grain boundaries; in other words, Zn remains in the shallower part of the grain boundaries, thus reducing the likelihood of LME cracking. Specifically, if the Mg concentration in the front end 60a of the Zn intrusion zone 60 is high, it hinders the diffusion of Zn into the steel grains, leading to the easy formation of a Zn intrusion zone containing a high Zn concentration. That is, if the Mg concentration is high, LME cracking is more likely to occur; if the Mg concentration is kept low, LME cracking becomes less likely to occur.

[0087] As described below, in the welded joint 100, at least one of the first steel plate 10 and the second steel plate 20 can be a steel plate that has undergone internal oxidation treatment. In this case, Zn is unlikely to become a liquid phase at the surface of the steel plates 10 and 20. Furthermore, when the welded joint 100 is constructed using steel plates 10 and 20 that have undergone internal oxidation treatment, even if Zn and Mg in the plating layers 11 and 21 become liquid phases during spot welding, the liquid phases of Zn and Mg tend to remain at a high concentration near the surface of the steel plates 10 and 20, making it difficult for the liquid phases of Zn and Mg to penetrate deep into the grain boundaries. As a result, the Mg concentration in the front end portion 60a of the Zn penetration portion 60 tends to be low. The Mg concentration in the front end portion 60a can also be 0.15% by mass or less or 0.10% by mass or less.

[0088] The Zn-infiltrated portion 60 may also contain components other than Zn and Mg. For example, the Zn-infiltrated portion 60 may also contain Al, Si, Fe, etc. Furthermore, the Zn-infiltrated portion 60 may also contain other elements or impurities derived from the coating or steel plate. There are no particular limitations on the microstructure of the Zn-infiltrated portion 60.

[0089] 1.7 Supplement

[0090] As described above, in the welded joint 100, at least one of the first steel plate 10 and the second steel plate 20 may be a steel plate that has undergone internal oxidation treatment. For example, in the welded joint 100, at least one of the first steel plate 10 and the second steel plate 20 may have an internal oxide layer with a depth of 1.5 μm to 20.0 μm. More specifically, for example, the welded joint 100 may also have an internal oxide layer with a depth of 1.5 μm to 20.0 μm on one side of the first steel plate 10 opposite to the second steel plate 20. It should be noted that the "depth" of the internal oxide layer refers to the depth from the surface of the steel plate (base metal). When at least one of the first steel plate 10 and the second steel plate 20 has a specified internal oxide layer, as described above, the Mg concentration in the front end 60a of the Zn intrusion portion 60 tends to be lower, which easily suppresses LME cracking. In particular, LME cracking in the steel plate with the internal oxide layer is easily suppressed.

[0091] As described above, the welded joint 100 may include both a first plating layer 11 and a second plating layer 21. For example, the first plating layer 11 may be present on the surface of the first steel plate 10 opposite to the second steel plate 20. Furthermore, the second plating layer 21 may be present on the surface of the second steel plate 20 opposite to the first steel plate 10. Additionally, at least one of the first plating layer 11 and the second plating layer 21 may contain both Zn and Mg. Furthermore, the boundary plating layer 50 may also contain components derived from the first plating layer 11 and components derived from the second plating layer 21.

[0092] In the above description, the welded joint 100 has been described as having a first steel plate 10 and a second steel plate 20. However, in addition to having a first steel plate 10 and a second steel plate 20, the welded joint 100 may also have other steel plates. That is, the welded joint 100 may also be a joint obtained by overlapping three or more steel plates and joining them by spot welding. Furthermore, the welded joint 100 may also have multiple spot weld portions. In any case, the welded joint 100 only needs to have the first steel plate 10, the second steel plate 20, the spot weld portion 30, and the portion considered as the boundary plating layer 50 in at least a portion. That is, when multiple spot weld portions are provided, there may be spot weld portions in a portion of the multiple boundary plating layers that do not meet the conditions of the boundary plating layer 50 described above.

[0093] 2. Manufacturing method of welded joints

[0094] The manufacturing method of the welded joint 100 may include: (1) manufacturing a first steel plate 10 and a second steel plate 20, wherein a first plating layer 11 is provided on the surface of the first steel plate 10 opposite to the second steel plate 20, and the surface of the second steel plate 20 opposite to the first steel plate 10 either has no plating layer or has a second plating layer 21, wherein at least one of the first plating layer 11 and the second plating layer 21 comprises Zn and Mg; and (2) spot welding is performed on the basis of overlapping the first steel plate 10 and the second steel plate 20 in a manner that sandwiches the plating layers. Hereinafter, an example of the manufacturing method of the welded joint 100 will be described, but the welded joint 100 may also be manufactured by other methods.

[0095] 2.1 Manufacturing conditions of steel plates

[0096] Steel sheets can be obtained, for example, by performing the following processes: a casting process in which molten steel with adjusted composition is cast to form a billet; a hot rolling process in which the billet is hot-rolled to obtain a hot-rolled steel sheet; a coiling process in which the hot-rolled steel sheet is coiled; a cold rolling process in which the coiled hot-rolled steel sheet is cold-rolled to obtain a cold-rolled steel sheet; a pretreatment process in which the cold-rolled steel sheet is electroplated; and an annealing process in which the pretreatment cold-rolled steel sheet is annealed. Alternatively, after the hot rolling process, coiling can be omitted, and the sheet can be pickled and then directly subjected to the cold rolling process. Afterward, a coated steel sheet is manufactured by coating the surface of the steel sheet.

[0097] (Casting process)

[0098] There are no particular restrictions on the conditions of the casting process. For example, after smelting in a blast furnace or electric furnace, various secondary refining processes can be carried out, followed by casting through conventional continuous casting or casting using ingot casting methods.

[0099] (Hot rolling process)

[0100] Hot-rolled steel sheets can be obtained by hot rolling cast steel billets as described above. The hot rolling process involves directly hot rolling the cast steel billet or temporarily cooling it before reheating and hot rolling. In the case of reheating, the billet heating temperature can be, for example, 1100℃ to 1250℃. The hot rolling process typically includes roughing and finishing rolling. The temperature and reduction rate of each rolling stage can be appropriately adjusted according to the desired microstructure and plate thickness. For example, the finishing rolling end temperature can be set to 900℃ to 1050℃, and the finishing rolling reduction rate can be set to 10% to 50%.

[0101] (Winding process)

[0102] Hot-rolled steel sheets can be coiled at a specified temperature. The coiling temperature can be adjusted appropriately according to the desired metal structure, for example, 500–800°C. Alternatively, the hot-rolled steel sheet can be uncoiled before or after coiling and subjected to a specified heat treatment. Alternatively, the coiling process can be omitted, and pickling followed by the cold rolling process described later can be performed.

[0103] (Cold rolling process)

[0104] After pickling and other processes, hot-rolled steel sheets can be cold-rolled to obtain cold-rolled steel sheets. The reduction rate during cold rolling can be appropriately adjusted according to the desired metal structure and sheet thickness, for example, from 20% to 80%. After the cold rolling process, the sheet can be cooled to room temperature, for example, by air cooling.

[0105] (Pre-processing step)

[0106] When a predetermined pretreatment process is performed before annealing the cold-rolled steel sheet, the external oxide film formed on the surface of the steel sheet during the rolling process is appropriately removed. During annealing, oxygen can more easily penetrate the interior of the steel, promoting the formation of oxides within the steel sheet. Furthermore, it is possible to promote the formation of oxides within the steel sheet by introducing strain or the like on the surface. In other words, with such a pretreatment process, the desired internal oxides are more easily generated during the annealing process described later. This pretreatment process may also include grinding or electrolytic treatment using brushes or the like. For example, grinding may include applying an aqueous solution containing 0.5–4.0% by mass NaOH to the cold-rolled steel sheet and performing brush grinding with a brush reduction of 0.5–4.0 mm and a rotation speed of 200–1200 rpm. Electrolytic treatment may include, for example, energizing the cold-rolled steel sheet in a solution with a pH of 8.0 or higher. The current density during energization is 1.0–8.0 A / dm³. 2It is advisable to use pH, current density, and energizing time that are within these parameters. By controlling the pH, current density, and energizing time during the energizing process, internal oxides can be effectively formed during the annealing process described later.

[0107] (Annealing process)

[0108] Annealing is preferably performed under a tension of 0.1 to 20 MPa. When tension is applied during annealing, strain can be introduced into the steel sheet more effectively, and oxides are more easily formed inside the steel sheet.

[0109] To ensure proper formation of the internal oxide layer, the holding temperature during the annealing process is preferably 700–900°C, and more preferably 720–870°C. Setting the temperature within this range helps suppress the formation of the external oxide layer and allows oxides to form internally within the steel sheet. If the holding temperature is below 700°C, the desired internal oxide layer may not form sufficiently during annealing. If the holding temperature exceeds 900°C, the external oxide layer is more easily formed during annealing. The heating rate up to the holding temperature is not particularly limited, but a rate of 1–10°C / second is acceptable. Alternatively, the heating can be performed in two stages: a first heating rate of 1–10°C / second and a second heating rate of 1–10°C / second, different from the first heating rate.

[0110] The holding time at the holding temperature in the above-mentioned annealing process can be 10 to 300 seconds, or 30 to 250 seconds. By setting it within this range, the formation of an external oxide layer can be suppressed, and oxides can be formed inside the steel sheet. If the holding time is less than 10 seconds, the desired internal oxide may not be sufficiently formed during annealing. If the holding time exceeds 300 seconds, an external oxide layer is more likely to form during annealing.

[0111] From the viewpoint of fully generating internal oxides, the dew point of the atmosphere in the annealing process should preferably be -20 to 10°C, and more preferably -10 to 5°C.

[0112] Furthermore, oxides (typically including grain boundary oxides) formed inside the steel sheet during previous processes can be removed before the annealing process. An internal oxide layer may form on the surface of the steel sheet during the aforementioned rolling processes, particularly hot rolling. This internal oxide layer formed during such rolling processes may hinder the formation of internal oxides during the annealing process; therefore, it can also be removed before annealing by pickling or similar treatments. For example, to anticipate the growth of the internal oxide layer during the annealing process, it is preferable to set the depth of the internal oxide layer in the cold-rolled steel sheet before annealing to be less than 1.5 μm, less than 1.0 μm, less than 0.5 μm, less than 0.3 μm, less than 0.2 μm, or less than 0.1 μm.

[0113] As described above, when manufacturing steel plates 10 and 20, it is effective to form internal oxides on the surface layer of the steel plates (e.g., the region from the surface of the steel plate to 20 μm, i.e., the interior of the steel plate). For example, in order to suppress LME cracking in the first steel plate 10, it is preferable to form the aforementioned internal oxides on the surface layer of the first steel plate 10. Examples of such internal oxides include granular oxides dispersed in a granular manner within the grains or at the grain boundaries of the steel, grain boundary oxides existing along the grain boundaries of the steel, and / or dendritic oxides existing in a dendritic manner within the grains. When internal oxidation treatment is performed on the steel plates 10 and 20, for example, the Si contained in the steel plates 10 and 20 is oxidized, resulting in a state of Si deficiency at the surface layer of the steel plates 10 and 20. According to the inventor's new understanding, if Si is lacking at the surface layer of the steel plates 10 and 20, Zn becomes difficult to form a liquid phase at the surface layer of the steel plates 10 and 20. That is, in the welded joint 100, when at least one of the first steel plate 10 and the second steel plate 20 has undergone suitable internal oxidation treatment, Zn is difficult to become a liquid phase at the surface of the steel plates 10 and 20. As a result, Zn becomes difficult to penetrate into the interior of the steel plates 10 and 20, which can suppress LME cracking. When an oxide film is formed on the surface (outside) of the steel plates 10 and 20, that is, when an external oxide layer is formed, it is difficult to obtain the above-mentioned effect.

[0114] 2.2 Plating process

[0115] A coating is formed on the surface of a steel sheet through a plating process. The plating process can be performed according to methods known to those skilled in the art. For example, the plating process can be performed by hot-dip plating, electroplating, or vapor deposition. Hot-dip plating is preferred. The conditions of the plating process can be appropriately set considering the desired coating composition, thickness, and adhesion amount. Alloying can also be performed after the plating process. Typically, the conditions of the plating process are preferably set to form a coating comprising: Al: 0–90.0%, Mg: 0–60.0%, Fe: 0–15.0%, and Si: 0–10.0%, with the remainder consisting of Zn and impurities.

[0116] 2.3 Spot welding conditions

[0117] After manufacturing steel plates 10 and 20 as described above, overlap steel plates 10 and 20 and spot weld at least one location. The spot welding conditions can be any conditions known to those skilled in the art. For example, a welding electrode with a dome radius and a front diameter of 6–8 mm can be used, with a pressure of 1.5–6.0 kN, an energizing time of 0.1–1.0 seconds (5–50 cycles, power frequency of 50 Hz), and an energizing current of 4–15 kA for spot welding.

[0118] As described above, and as in the welded joint 100 of this disclosure, by satisfying the prescribed relationship I through the first coating 11 and the second coating 21, the Mg concentration in the front end 60a of the Zn intrusion portion 60 is satisfied to a predetermined value or less, thereby easily suppressing LME cracking and easily ensuring excellent corrosion resistance.

[0119] 3. Applications of welded joints

[0120] The welded joint 100, as described above, readily suppresses LME cracking and exhibits excellent corrosion resistance, making it suitable for various applications. For example, it is preferably suitable for automotive parts. In a preferred embodiment, the automotive part includes the aforementioned welded joint 100, with a first steel plate 10 disposed on the outer side of the vehicle and a second steel plate 20 disposed on the inner side of the vehicle. The Mg composition of the second coating 21 is lower than that of the first coating 11. Furthermore, in this automotive part, the ratio of [Mg composition (mass %) of the first coating] to [Zn composition (mass %) of the first coating] can also be greater than 0.01.

[0121] Automotive components are composed of multiple steel sheets. When steel sheets are overlapped in an automotive component, the steel sheets located on the outer side of the vehicle are required to have higher corrosion resistance than those located on the inner side. To meet this requirement, a high-Mg coating can be applied to the surface of the steel sheets located on the outer side of the vehicle. On the other hand, from a corrosion resistance perspective, it is not necessary to increase the Mg content in the coating of the steel sheets located on the inner side of the vehicle compared to those on the outer side. If there is a concern about LME cracking at the weld joint with the steel sheets located on the inner side of the vehicle due to the high-Mg coating on the surface of the outer side of the vehicle, this can be addressed by setting the Mg / Zn content ratio and coating thickness (adhesion amount) of the coating on the outer surface of the inner side of the vehicle to a range that satisfies the aforementioned Relationship I. This allows for a balance between the corrosion resistance of the automotive component and the integrity of the weld joint. Furthermore, as described in the preferred embodiment, even if the first coating has a composition that is likely to cause LME cracking, LME cracking can be suppressed by suppressing the Mg composition of the second coating. Furthermore, even if the composition of the first coating is calculated individually without the generation of LME cracking, the weld joint can be prevented from becoming insufficiently corrosion resistant by adjusting the composition and adhesion amount of the second coating.

[0122] The welded joint 100 disclosed herein is applicable to all automotive parts in which the first steel plate 10 and the second steel plate 20 are joined by a spot weld 30. Figure 4 The image shows one embodiment of an automotive component 1000. For example... Figure 4 As shown, the automotive component 1000 may also include a cap-shaped member 200 disposed on the outer side of the vehicle, a reinforcing member 300 disposed on the inner side of the vehicle, and a closing plate 400. Alternatively, the automotive component 1000 may not include the reinforcing member 300. In the automotive component 1000, for example, the cap-shaped member 200 may also correspond to the first steel plate 10 in the aforementioned welded joint 100. Furthermore, in the automotive component 1000, for example, the reinforcing member 300 may also correspond to the second steel plate 20 in the aforementioned welded joint 100. Furthermore, in the automotive component 1000, for example, the closing plate 400 may also correspond to the second steel plate 20 in the aforementioned welded joint 100.

[0123] Example

[0124] The effects of the welded joints of this disclosure will be further explained below while illustrating the embodiments, but the welded joints of this disclosure are not limited to these embodiments.

[0125] 1. Steel plate manufacturing

[0126] The steel molten material with adjusted composition was cast to form a steel billet, which was then hot-rolled, pickled, and cold-rolled to obtain a cold-rolled steel sheet. Next, the sheet was air-cooled to room temperature, and then pickled to remove the internal oxide layer formed during rolling. Following this, a portion of the cold-rolled steel sheets underwent brush grinding and electrolytic treatment. Brush grinding was performed twice with a brush depth of 2.0 mm and a rotation speed of 600 rpm, while the cold-rolled steel sheet was coated with an aqueous solution containing 2.0% NaOH. Electrolytic treatment involved immersing the cold-rolled steel sheet in a solution at pH 9.8 at 6.1 A / dm³. 2The current density was applied for 7.2 seconds. Afterwards, annealing was performed according to the specified dew point, holding temperature, and holding time to produce various steel sheets. For all steel sheets, the heating rate during annealing was set to 6.0°C / second up to 500°C, and 2.0°C / second from 500°C to the holding temperature. The holding temperature was 800°C and the holding time was set to 100 seconds, with a holding atmosphere of N2-4%H2 and a dew point of 0°C. In the above annealing process, some cold-rolled steel sheets were annealed under a tension of 0.5 MPa, while other cold-rolled steel sheets were annealed without tension. Furthermore, for each steel sheet, JIS No. 5 tensile test specimens were collected with the length direction perpendicular to the rolling direction as the longitudinal direction, and tensile tests were performed according to JIS Z 2241 (2011). The thickness of all steel sheets used was 1.6 mm.

[0127] 2. Plating

[0128] After cutting each steel plate into 100mm × 200mm dimensions, each plate underwent hot-dip galvanizing, followed by alloying. In the hot-dip galvanizing process, the cut samples were immersed in a 440℃ galvanizing bath for 3 seconds. After immersion, they were drawn at 100mm / second, and the coating adhesion was controlled using N2 wiping gas. The cooling rate after coating was set to 10℃ / second, cooling from the bath temperature to below 150℃ to obtain the samples. Subsequently, a portion of the samples underwent alloying treatment at 500℃ to obtain alloyed Zn-based coated steel plates.

[0129] 3. Spot welding

[0130] The welded joint was obtained as follows: Two samples were prepared by cutting each Zn-based coated steel sheet into 50mm × 100mm dimensions. For these two Zn-based coated steel sheet samples, a dome-radius type welding electrode with a front diameter of 8mm was used. Spot welding was performed with an angle of 3°, a pressure of 3.0kN, an energizing time of 0.5 seconds (20 cycles, power frequency of 50Hz), an energizing current of 7kA, and a plate gap of 0.3mm. It should be noted that "angle of 3°" refers to the degree of tilt between the electrode and the steel plate from 90°. For example, an angle of 3° means welding with the electrode and steel plate in contact at an angle of 87°.

[0131] 4. Analysis and calculation of the metallic composition of the coating

[0132] For each welded joint obtained, the chemical composition of the first coating formed on the surface of the first steel plate opposite to the second steel plate and the chemical composition of the second coating formed on the surface of the second steel plate opposite to the first steel plate were analyzed, and the average Mg / Zn ratio was calculated as follows. The composition analysis of the first and second coatings focused on portions at least 10 mm away from the boundary coating or portions not subjected to welding. The composition of the coatings was determined by immersing samples cut into 30 mm × 30 mm pieces in 10% hydrochloric acid with added inhibitor to dissolve the coating, and then performing ICP analysis on the coating components dissolved in the solution.

[0133] Average Mg / Zn = [(Mg composition of the first coating (mass%)) × (Adhesion amount of the first coating (g / m)) 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]

[0134] 5. Elemental analysis of the front end of the Zn intrusion region

[0135] For each weld joint obtained, the Zn concentration was measured along the Zn-infiltrated grain boundaries until it fell below 0.1%. The point where the Zn concentration reached 0.1% was considered the tip of the Zn intrusion, and the Mg concentration in this tip was measured. Specifically, TEM observation was performed using a JEM-2100F (JEOL Ltd.), and TEM-EDS measurement was performed at an accelerating voltage of 200 kV to determine the Zn concentration. The thin-film test piece used for TEM observation was cut out using FIB processing after determining the location of the Zn intrusion by cross-sectional SEM observation of the weld joint.

[0136] 6. Evaluation of the presence or absence of LME cracking

[0137] The spot welds of each welded joint were observed to evaluate the presence or absence of LME cracking. The evaluation criteria are as follows.

[0138] Rating AA: No LME cracking

[0139] Evaluation A: LME crack length exceeds 0 μm but is less than 100 μm

[0140] Rating B: LME crack length exceeding 100 μm but less than 300 μm

[0141] Rating C: LME crack length exceeds 300μm

[0142] 7. Corrosion Resistance Evaluation

[0143] For each welded joint, a composite cyclic corrosion test was conducted according to JASO (M609-91), and the corrosion resistance of the spot weld was evaluated by observing the corrosion condition of the steel after 120 cycles. For each evaluation sample, after the above corrosion test was completed, the cross-section including the spot weld (melt nugget and ductile metal ring area) and the steel plate was observed by SEM (e.g., Figure 1 That part). The direction from the boundary coating toward the steel plate is determined by observing the image (e.g., Figure 1 The corrosion resistance is evaluated based on the following criteria: the maximum corrosion depth of the steel plate portion within a 1mm range (center to top).

[0144] Evaluation A: Corrosion depth less than 0.3mm

[0145] Rating B: Corrosion depth exceeding 0.3 mm but less than 0.5 mm

[0146] Rating C: Corrosion depth ≥ 0.5mm

[0147] 8. Evaluation Results

[0148] The following table shows the strength, plating composition and other properties of the first and second steel plates used in each weld joint, the Mg concentration in the front end of the Zn intrusion, the evaluation results of LME cracking of the weld joint, and the evaluation results of the corrosion resistance of the weld joint.

[0149]

[0150]

[0151] (Table 3)

[0152]

[0153] As the results shown in Tables 1-3 indicate, LME cracking is significantly suppressed and corrosion resistance is ensured when the welded joint meets the following necessary conditions (No. 2-5, 8-11, 14-19, 20, 23, 24, 26, 27).

[0154] (1) The first steel plate has a first coating on the surface opposite to the second steel plate, and the second steel plate has no coating or has a second coating on the surface opposite to the first steel plate.

[0155] (2) The first coating and the second coating satisfy the following relationship I.

[0156] (3) Between the first steel plate and the second steel plate, and within a range of 0.5 mm from the end of the plastic metal ring region toward the outside of the spot weld, there is a boundary coating. In at least one of the first steel plate and the second steel plate adjacent to the boundary coating, there is a Zn intrusion portion that progresses along the steel grain boundary from the boundary coating.

[0157] (4) The Mg concentration at the front end of the Zn intrusion site and at the Zn concentration of 0.1% by mass is less than 0.20% by mass.

[0158] Relationship I: 0.010 ≥ [(Mg composition (mass%) of the first coating layer) × (attachment amount of the first coating layer) + (Mg composition (mass%) of the second coating layer) × (attachment amount of the second coating layer)] / [(Zn composition (mass%) of the first coating layer) × (attachment amount of the first coating layer) + (Zn composition (mass%) of the second coating layer) × (attachment amount of the second coating layer)] ≥ 0.001

[0159] In the absence of a second coating, the Mg composition, Zn composition, and adhesion amount of the second coating are all 0.

[0160] In particular, when the first and second coatings satisfy the following relationship I-1, the weld joint becomes a weld joint with even better LME crack suppression effect.

[0161] Relationship I-1: 0.006 ≥ [(Mg composition of the first coating layer (mass%)) × (adhesion amount of the first coating layer (g / m)) 2 ))+(Mg composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m)) 2 ))] / [(Zn composition of the first coating (mass%))×(Adhesion amount of the first coating (g / m)) 2 ))+(Zn composition of the second coating (mass%))×(Adhesion amount of the second coating (g / m) 2 ))]≥0.001

[0162] It should be noted that for No.1 and No.12, due to the large average Mg / Zn ratio of the coating, the Mg concentration at the front end of the Zn intrusion part also increases, which makes it difficult to suppress LME cracking.

[0163] Regarding No. 6 and No. 7, since brush grinding or tension control was not performed during the internal oxidation treatment of cold-rolled steel sheets, the morphology of the internal oxides could not be properly controlled, and the Mg concentration at the front end of the Zn intrusion zone increased, resulting in difficulty in suppressing LME cracking.

[0164] Regarding No. 13, since the average Mg / Zn ratio of the coating is 0, meaning that there is no Mg in the coating, sufficient corrosion resistance cannot be guaranteed.

[0165] As shown in Tables 1-3 above, even without a second coating, as long as Relation I and the Mg concentration at the Zn intrusion site's leading edge meet the aforementioned necessary conditions, both LME crack suppression and corrosion resistance can be achieved. Examples without a second coating are No. 20, 21, 22, 23, and 26. Among these, No. 20, 23, and 26 meet the aforementioned necessary conditions for Relation I and the Mg concentration at the Zn intrusion site's leading edge. That is, No. 20, 23, and 26 are examples. These examples achieve a balance between LME crack suppression and corrosion resistance. On the other hand, No. 21, since it deviates from the lower limit of Relation I, does not achieve sufficient corrosion resistance. Furthermore, No. 22, since it deviates from the upper limit of Relation I and also from the upper limit of the Mg concentration at the Zn intrusion site's leading edge, cannot suppress LME cracking.

[0166] Furthermore, even when both the first and second coatings contain Mg, as long as the necessary conditions for Relation I and the Mg concentration at the Zn intrusion point are met, a balance between LME crack suppression and corrosion resistance can be achieved. Examples where both the first and second coatings contain Mg are No. 24 and 25. No. 24 is an example where the necessary conditions for Relation I and the Mg concentration at the Zn intrusion point are met. No. 24 achieves a balance between LME crack suppression and corrosion resistance. On the other hand, No. 25, since it deviates from the upper limit of Relation I and the upper limit of the Mg concentration at the Zn intrusion point, cannot suppress LME cracking.

[0167] Furthermore, the internal oxide layer will be described in more detail below. While Nos. 6 and 7 satisfy Relation I, they fail to suppress LME cracking because they deviate from the upper limit of the Mg concentration at the Zn intrusion tip. Examples of Relation I values ​​equivalent to Nos. 6 and 7 are Nos. 2, 18, and 19. In these examples, at least one of the first and second steel plates has an internal oxide layer with a depth of 1.5 μm or more. That is, if an internal oxide layer with a depth of 1.5 μm or more is present, the Mg concentration at the Zn intrusion tip when Relation I is satisfied becomes lower compared to the case without an internal oxide layer with a depth of 1.5 μm or more, making it easier to suppress LME cracking. No. 27 is an example where Relation I and the Mg concentration at the Zn intrusion tip satisfy the aforementioned necessary conditions. Examples of Mg concentrations at the Zn intrusion tip equivalent to No. 27 are Nos. 5, 15, 16, 23, 24, and 26. The Relation I values ​​of these examples are approximately three times that of No. 27. That is, as in No. 27, when the depth of the internal oxide layer is less than 1.5 μm, if the value of relation I is not reduced, the upper limit of the Mg concentration at the front end of the Zn intrusion site will be exceeded. Therefore, it can also be concluded that the presence of an internal oxide layer with a depth of 1.5 μm or more helps to suppress the Mg concentration at the front end of the Zn intrusion site.

[0168] Explanation of symbols

[0169] 10 First Steel Plate

[0170] 11 First coating

[0171] 20 No. 2 steel plate

[0172] 21 Second coating

[0173] 30 Spot welds

[0174] 31 Melting Core

[0175] 32 Plastic Metal Ring Region

[0176] 40 Separation Section

[0177] 50 Boundary Coating

[0178] 60 Zn Intrusion Section

[0179] 100 Welded Joint

[0180] 200 Hat-shaped component

[0181] 300 Reinforcing Components

[0182] 400 Closed Panel

Claims

1. A welded joint comprising a first steel plate, a second steel plate, and a spot weld portion for joining the first steel plate and the second steel plate. A first coating is provided on the surface of the first steel plate opposite to the second steel plate. On the surface of the second steel plate opposite to the first steel plate, there is either no coating or a second coating is present. The spot weld section has a weld nugget and a plastic metal ring region. A boundary plating layer is provided between the first steel plate and the second steel plate, and within a range of 0.5 mm from the end of the plastic metal ring region toward the outer side of the spot weld. In at least one of the first steel plate and the second steel plate adjacent to the boundary coating, there is a Zn intrusion portion. The Zn intrusion portion extends along the steel grain boundaries from the boundary coating. The Mg concentration at the front end of the Zn intrusion section, where the Zn concentration is 0.1% by mass, is below 0.20% by mass. The first coating and the second coating satisfy the following relationship I. Relationship I: 0.010 ≥ [(Mg composition of the first coating in mass %) × (Mg composition of the first coating in g / m 2 (Adhesion amount) + (Mg composition of the second coating in mass %) × (Mg composition of the second coating in g / m 2 [(adhesion amount)] / [(Zn composition of the first coating in mass %) × (the amount of the first coating in g / m 2 (Adhesion amount) + (Zn composition of the second coating in mass %) × (Zn composition of the second coating in g / m 2 [Accumulated amount of adhesion] ≥ 0.001 in, In the absence of the second coating, the Mg composition, Zn composition, and adhesion amount of the second coating are 0.

2. The welded joint according to claim 1, wherein, The first coating and the second coating satisfy the following relationship I-1, Relationship I-1: 0.006 ≥ [(Mg composition of the first coating in mass %) × (Mg composition of the first coating in g / m 2 (Adhesion amount) + (Mg composition of the second coating in mass %) × (Mg composition of the second coating in g / m 2 [(adhesion amount)] / [(Zn composition of the first coating in mass %) × (the amount of the first coating in g / m 2 (Adhesion amount) + (Zn composition of the second coating in mass %) × (Zn composition of the second coating in g / m 2 [The amount of adhesion (calculated)] ≥ 0.

001.

3. The welded joint according to claim 1 or 2, wherein one or more oxides with a major diameter of 0.5 μm or more are present in the boundary coating.

4. The welded joint according to claim 1 or 2, wherein the first steel plate has an internal oxide layer with a depth of 1.5 μm to 20.0 μm on one side of the surface of the first steel plate opposite to the second steel plate.

5. The welded joint according to claim 1 or 2, wherein, The tensile strength of the steel plate having the Zn intrusion portion in the first steel plate and the second steel plate is 590 MPa or higher.

6. An automotive component comprising a welded joint as described in any one of claims 1 to 5. The first steel plate is positioned on the outer side of the vehicle. The second steel plate is located on the inside of the vehicle. The Mg composition of the second coating is lower than that of the first coating.

7. The automotive component according to claim 6, wherein, The ratio of the mass percentage of Mg in the first coating to the mass percentage of Zn in the first coating is greater than 0.01.