Method for welding a zinc coated steel sheet

Abstract

A method for welding a zinc coated steel sheet is provided. The method for welding a zinc coated steel sheet of the present invention is a method for welding a zinc coated steel sheet by using a welding material, wherein when welding, the welding current is 150-300 A, a shielding gas is a mixed gas of Ar+10-30% CO2, and the welding polarity is alternately altered so that the welding polarity fraction defined by relational equation 1 satisfies the range of 0.25-0.35.

Claims

1. A lap-joint welding method of welding a first zinc coated steel sheet and a second zinc coated steel sheet stacked to partially overlap the first zinc coated steel sheet using a welding wire, to reduce a porosity defect of welded metal, comprising: welding, wherein the welded metal has a pore area ratio of 0.97% or less and have a tensile strength of 700 MPa or more, wherein a gap of a welded joint formed by the method is 0 mm, wherein the welding current is supplied as a bidirectional pulse current in which positive direct current and negative direct current are of equal and constant absolute value in a range from 200 A to 270 A, and wherein a welding polarity is alternately altered to satisfy a welding polarity fraction, in a range of 0.25 to 0.35, the welding polarity being defined by
EN.sub.R,%/(EP.sub.R,%+EN.sub.R,%) where, EN.sub.R, % is a fraction of time for which current through the welding wire is negative direct current, and EP.sub.R, % is a fraction of time for which current through the welding wire is positive direct current.

2. The method of claim 1, wherein the welding wire is an E70C-GS 1.0 metal cored wire.

3. The method of claim 1, wherein the zinc coated steel sheet is HGI 780HB steel.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a schematic diagram illustrating polarity fractions of arc welding currents according to an embodiment of the present invention.

(2) FIG. 2 is a cross-sectional photograph of a welded bead before and after optimizing polarity fractions of arc welding currents of a zinc coated steel sheet (where, a welding target base material, used, is HGI 780Hyber Burr having 2.0 mm thickness, a tensile strength of 810 MPa, and a plating amount on one side of 100 g/m.sup.2).

(3) FIG. 3 is a photograph showing an appearance of a welded portion and results of X-ray transmissions of the welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet (a welding rate of 100 cm/min).

(4) FIG. 4 is a graph illustrating results of measuring hardness of a welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet.

(5) FIG. 5 is a graph showing results of tensile curves of a welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet.

BEST MODE FOR INVENTION

(6) Hereinafter, the present invention will be described.

(7) The inventors of the present invention confirmed that zinc vapor may be effectively discharged externally by optimally controlling polarity fractions of arc welding current when lap-joint welding a zinc coated steel sheet to vibrate a molten pool formed by welding, and porosity defects of a welded metal may be ultimately reduced, to complete the present invention.

(8) For example, a method for welding a zinc coated steel sheet of the present invention relates to a method for lap-joint welding a zinc coated steel sheet using a welding wire, wherein, when welding, a welding current is 150 to 300 A, a shielding gas is a mixed gas of Ar+10 to 30% CO.sub.2, and a welding polarity is alternately altered to satisfy a welding polarity fraction, defined by the following relationship 1, in a range of 0.25 to 0.35.

(9) First, the present invention relates to a method for lap-joint welding a zinc coated steel sheet.

(10) The lap-joint welding method may refer to a method of welding a first zinc coated steel sheet and a second zinc coated steel sheet stacked to partially overlap the first zinc coated steel sheet, while forming a welded metal by an overlapping arc welding process.

(11) In the present invention, the zinc coated steel sheet may include a conventional hot-rolled or cold-rolled zinc coated steel sheet, and further, the coated steel sheet may be a ZnMgAl-based alloy-plated steel sheet.

(12) In the present invention, a first zinc coated steel sheet and a second zinc coated steel sheet stacked to partially overlap the first zinc coated steel sheet may be joined to form a welded metal by an arc welding process. For example, after preparing the first zinc coated steel sheet and the second zinc coated steel sheet, a welding line may be formed by stacking the second plated steel sheet on the first plated steel sheet to partially overlap them. Then, welding current may be supplied to a welding wire while providing a shielding gas along the formed welding line, to generate an arc to proceed with the arc welding process.

(13) In the present invention, at this time, an overlapping width of a welded joint may be about 25 mm, when applied, but is not limited thereto.

(14) In addition, in the present invention, the welding wire may be an E70C-GS 1.0 metal cored wire, and is not particularly limited to a type and a component of the welding wire.

(15) The welding current during welding is preferably limited to 150 A or more and 300 A or less, and more preferably limited to 200 A or more and 270 A or less. When the current is too low, an effect of discharging plating vapor may decrease due to reduction of arc force. When the current is too high, a molten welded metal portion may be unstable and occurrence of porosity defects may increase.

(16) In addition, in the present invention, it may be necessary to mix 10 to 30% CO.sub.2 with Ar as a shielding gas during welding. For example, the shield gas may be Ar gas, and may contain 10 to 30% of CO.sub.2 gas. When the CO.sub.2 gas is included in an amount less than 10%, an arc heat pinch force effect may decrease due to arc expansion to reduce a plating vapor discharge effect. In addition, when the CO.sub.2 gas is included in an amount exceeding 30%, the arc heat pinch force effect may excessively increase due to arc contraction to reduce the plating vapor discharging effect.

(17) In addition, in the present invention, during the arc welding, a welding torch angle in the range of 30 to 45 and a progress angle in the range of 0 to 25 may be managed.

(18) In addition, in the present invention, a gap of a welded joint formed 0 mm may be applied, but is not particularly limited thereto.

(19) In lap-joint welding a zinc coated steel sheet, during arc welding, a zinc coated layer having a low boiling point may become zinc gas due to arc heat, and may float to an upper portion of a molten pool. In this case, most thereof may be discharged, but a portion thereof may remain to form a blowhole, which may be a hollow cavity when solidified. Therefore, there may be problems in that a welded metal manufactured by welding has porosity defects, and thus, a welded metal having excellent tensile strength cannot be obtained.

(20) Therefore, the present invention may be provided to solve the problems, and may be characterized in that a welding polarity is alternately altered to satisfy a welding polarity fraction, defined by the following relationship 1, in a range of 0.25 to 0.35. Thereby, a molten pool formed by welding may be vibrated to discharge zinc vapor, to reduce a porosity defect of welded metal.
EN.sub.R,%/(EP.sub.R,%+EN.sub.R,%)[Relationship 1]
where, EN.sub.R,% is a welding polarity fraction of a negative electrode, and EP.sub.R,% is a welding polarity fraction of a positive electrode.

(21) FIG. 1 is a schematic diagram illustrating polarity fractions of arc welding current according to an embodiment of the present invention. As illustrated in FIG. 1, welding polarity fractions may be appropriately mixed and altered to increase vibration of a molten pool due to an increase in arc pressure and droplet transfer frequency, to promote an increase in discharge of zinc vapor.

(22) In the present invention, in order to effectively discharge the zinc vapor from the molten pool when lap-joint welding a zinc coated steel sheet, it may be characterized by controlling a welding polarity fraction (EP.sub.R,%) of a positive electrode of a welding wire and a welding polarity fraction (EN.sub.R,%) of a negative electrode of a welding target base material by the above relationship 1 to be within an appropriate value, and introduction of this concept may be due to the following technical idea.

(23) In a general case of a direct current electrode positive (DCEP) pulse, there may be a limitation in that a volume of a molten pool may increase due to an increase in heat input by to arc contraction, to reduce discharge of pores due to zinc vapor generated during welding. In contrast, when a DCEP and a direct current negative (DCEN) polarity are mixed in an appropriate fraction and altered, arc contraction and oxygen atmosphere may increase so that the increase of the negative electrode activation of the wire in a DCEN cycle could be realized. For example, during the DCEN cycle, occurrence of a cathode spot and arc concentration may be frequent on an upper end of the wire to heat the wire. Then, a current path may be maintained in a subsequent DCEP cycle, and an arc may be generated on the upper end of the wire. At this time, globular and spray droplet transfer modes may occur to simultaneously increase droplet transfer frequency and arc pressure pressurization frequency, to maximize discharge of pores generated in the molten pool.

(24) Therefore, in the case of a variable polarity arc, since the arc pressure and the droplet transfer may be irregular and high frequency, an effect of discharging the pores may be excellent. When a fraction of the DCEN polarity is lower than an appropriate value, the effect may be reduced when a value defined by the above relationship 1 is less than 0.25.

(25) In the case of a zinc coated steel sheet such as HGI, an arc may be eccentric on the DCEN polarity due to influence of a zinc coated layer. Therefore, an effective arc radius may decrease as a cathode spot may be distributed over a wide area on a surface of the target base material, or the cathode spot may be concentrated on a specific region, to reduce welding heat input efficiency. In addition, when a fraction of the DCEN polarity is high, coarse and unstable globular transfer and arcs may occur, and an exposure time of the cathode spot to the droplet may increase. Therefore, since unstable and excessive spatter may be generated due to occurrence of a cathode jet on a surface of the droplet, arc instability and reduction in discharging pores may appear. For example, when a fraction of the DCEN polarity exceeds the appropriate value (when a value defined by the relationship 1 exceeds 0.35), an adverse effect on suppressing the occurrence of porosity defects in the welded portion may occur.

(26) Hereinafter, the present invention will be described in detail through examples.

MODE FOR INVENTION

EXAMPLE

(27) Two (2) HGI 780Hyber Burring steel sheets having 2.0 mm thickness and a plating amount on one side of 100 g/m.sup.2 were made to overlap each other by 25 mm, and a connection portion therebetween was welded. Specifically, welding wires and welding conditions were used as shown in Tables 1 and 2, respectively, the HGI 780HB steel was lap-joint welded. At this time, the presence or absence of pit generation and pore area ratios were measured and shown in Table 1 below, and tensile strengths and fracture positions of welded portions were measured and shown in Table 2 below.

(28) TABLE-US-00001 TABLE 1 Welding Welding Conditions Pore Area No. Material (Current-Voltage-Rate) Current Properties Pit Ratios Example 1 ER705-61.2 202 A-20.6 V-0.6 m/min EP:EN = 100:0 X 1.55% CE1 2 ER70S-61.2 242 A-23.7 V-0.8 m/min EP:EN = 100:0, Pulse 12.67% CE2 3 ER70S-61.2 263 A-25.6 V-1.0 m/min EP:EN = 100:0, Pulse 20.60% CE3 4 ER70S-31.0 162 A-26.4 V-0.6 m/min EP:EN = 100:0, Pulse X 4.46% CE4 5 ER70S-31.0 217 A-28.9 V-0.8 m/min EP:EN = 100:0, Pulse X 5.70% CE5 6 ER70S-31.0 257 A-30.0 V-1.0 m/min EP:EN = 100:0, Pulse 8.25% CE6 7 E70C-GS1.0 214 A-24.0 V-1.0 m/min EP:EN = 50:50, Pulse X 2.51% CE7 8 E70C-GS1.0 213 A-24.0 V-1.0 m/min EP:EN = 60:40, Pulse X 2.34% CE8 9 E70C-GS1.0 214 A-24.0 V-1.0 m/min EP:EN = 65:35, Pulse X 0.97% IE1 10 E70C-GS1.0 209 A-24.0 V-1.0 m/min EP:EN = 70:30, Pulse X 0.87% IE2 11 E70C-GS1.0 216 A-24.2 V-1.0 m/min EP:EN = 75:25, Pulse X 0.94% IE3 12 E70C-GS1.0 210 A-24.0 V-1.0 m/min EP:EN = 80:20, Pulse X 1.52% CE9 *IE: Inventive Example, **CE: Comparative Example

(29) TABLE-US-00002 TABLE 2 Welding Welding Conditions Tensile Fracture No. Material (Current-Voltage-Rate) Current Properties Strength Position Example 1 ER70S-61.2 202 A-20.6 V-0.6 m/min EP:EN = 100:0 625 MPa Welded Metal CE1 2 ER70S-61.2 242 A-23.7 V-0.8 m/min EP:EN = 100:0, Pulse 599 MPa Welded Metal CE2 3 ER70S-61.2 263 A-25.6 V-1.0 m/min EP:EN = 100:0, Pulse 473 MPa Welded Metal CE3 4 ER70S-31.0 162 A-26.4 V-0.6 m/min EP:EN = 100:0, Pulse 690 MPa Heat Affected Zone CE4 5 ER70S-31.0 217 A-28.9 V-0.8 m/min EP:EN = 100:0, Pulse 678 MPa Heat Affected Zone CE5 6 ER70S-31.0 257 A-30.0 V-1.0 m/min EP:EN = 100:0, Pulse 670 MPa Heat Affected Zone CE6 7 E70C-GS1.0 214 A-24.0 V-1.0 m/min EP:EN = 50:50, Pulse 692 MPa Heat Affected Zone CE7 8 E70C-GS1.0 213 A-24.0 V-1.0 m/min EP:EN = 60:40, Pulse 696 MPa Heat Affected Zone CE8 9 E70C-GS1.0 214 A-24.0 V-1.0 m/min EP:EN = 65:35, Pulse 700 MPa Heat Affected Zone IE1 10 E70C-GS1.0 209 A-24.0 V-1.0 m/min EP:EN = 70:30, Pulse 702 MPa Heat Affected Zone IE2 11 E70C-GS1.0 216 A-24.2 V-1.0 m/min EP:EN = 75:25, Pulse 701 MPa Heat Affected Zone IE3 12 E70C-GS1.0 213 A-24.0 V-1.0 m/min EP:EN = 80:20, Pulse 698 MPa Heat Affected Zone CE9 *IE: Inventive Example, **CE: Comparative Example

(30) As shown in Tables 1 and 2, it can be seen that Inventive Examples 1 to 3 in which polarity fraction values defined by the relationship 1 satisfy the range of 0.25 to 0.35 and as well as welding conditions such as welding current and the like satisfy a given range had reduced effect of discharging zinc vapor to reduce porosity defects in a welded portion and improved a tensile strength of the welded portion, as compared to Comparative Examples 1 to 8 in which the polarity fraction values and the welding conditions do not.

(31) FIG. 2 is a cross-sectional photograph of a welded bead before (Comparative Example 8) and after (Inventive Example 2) optimizing polarity fractions of arc welding current of a zinc coated steel sheet, and FIG. 3 is a photograph showing an appearance of a welded portion and results of X-ray transmission of the welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet (welding rate of 100 cm/min), and FIG. 4 is a graph illustrating results of measuring hardness of a welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet of Inventive Example 2, and FIG. 5 is a graph showing results of tensile curves of a welded portion, after optimizing polarity fractions of arc welding current of a zinc coated steel sheet of Inventive Example 2 of the present invention.

(32) As can be seen in FIGS. 4 and 5, even at a welding rate of 100 cm/min, a hardness value of a welded metal portion was quite constant without a significant decrease due to porosity defects. In addition, it can be seen as a result of suppressing occurrence of porosity defects in the welded metal due to fracture in heat affected zones without fracture of the welded metal portions.

(33) While example embodiments have been shown and described above, it will be apparent to those skilled in the art that modifications and variations could be made without departing from the scope of the present invention as defined by the appended claims.