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J Weld Join > Volume 36(5); 2018 > Article
Das and Bang: Laser and Gas Metal Arc Based Dissimilar Joining of Automotive Aluminium Alloys and Steel Sheets - A Review

Abstract

Multi-material joining of aluminium to steel is mainly restricted due to their different thermo-physical properties, melting temperatures, low solubility and in particular, formation of brittle intermetallic phase layer at the joint interface. Various joining processes have been attempted to join aluminium and steel sheets with an aim to reduce the growth of phase layer by precise control of heat input. However, laser beam and arc based joining processes are popular among other joining processes due to their strict control of heat input with regulative metal transfer and flexibility to join intricate shapes. A critical survey in joining aluminium to steel sheets by laser beam and arc based joining processes are presented in the present work. The influence of various joining parameters such as heat input, filler wire types on the growth of intermetallic phase layer thickness and corresponding joint strength are analysed and reported subsequently.

1. Introduction

Joining of multi-material combinations such as aluminium to steel has gained significant attention in the automotive industry as a recourse to enhance the strength-to-weight ratio of the vehicle structures1-5). However, aluminium to steel joining is remain challenging due to their diverse thermo-physical properties, varying melting temperatures, poor solubility of aluminium in iron and in particular, formation of intermetallic phase layer with several Fe-Al brittle intermetallic compounds (IMC)6). Although presence of intermetallic phase layer is needed for the joint to form, however formation of thicker phase layer leads to embattlement of the joint5-7). Experimental studies indicate stringent control of the heat input is required to reduce the extent of formation of phase layer during joining of aluminium alloys and galvanized steel sheets7).
Various processes such as resistance spot welding (RSW)8), friction stir welding (FSW)9), laser beam10,11) and arc6,7,12-15) based joining techniques are attempted to join aluminium and steel with an aim to keep the heat input significantly low. Joining of complex contours using FSW remained a problem while severe electrode wear due to chemical reaction between copper electrode and aluminium alloys inhibited use of RSW process in joining of aluminium alloys as well as of aluminium and steel9,16). The use of laser and advanced pulsed current arc based joining processes is increasing in recent times due to their superior control over heat input with metal transfer rate, and flexibility to join out-of-position geometries5-7,10,11).

2. Motivation

Laser beam and pulsed current gas metal arc (GMA) based techniques could join thin metallic sheets of dissimilar materials at a very low power with moderate to reasonable high speed. The recently reported studies on application of laser beam and GMA based processes for joining of aluminium to steel sheets involved primarily the assessment of growth of intermetallic phase layer thickness with nature of IMCs at the joint interface and the corresponding joint strengths6,7,10,11). Laser beam and GMA based processes commonly employed pure Al, Al-Si, Al-Mg filler wires as well as without filler wire in joining aluminium to steel sheets5-7,10-14). Several authors found phase layer thickness in the range of 0.9 ~ 30 μm with corresponding joint strength around 80 ~ 201 MPa using pure Al, Al-Si, Al-Mg filler wires7,10-12,14,15). In another case, a heat input of 200 J mm-1 generated the phase layer thickness in the range of 3 ~ 5 μm with maximum joint strength around 200 MPa6). Most of the available studies reported usage of different types of filler wires with widely varying range of the heat input and phase layer thickness to obtain a sound and defect-free joint. In the present study, the current applications of laser beam and GMA based joining processes to make a suitable joint between aluminium alloys and different types of steel sheets are presented. The influence of joining parameters such as heat input, filler wire types and varieties of steel surface coating on growth of phase layer at the joint interface and corresponding joint strength are illustrated further in details.

3. Laser Beam Based Joining

Mathieu et al.17) used typical heat input range of 50 ~ 60 J mm-1 in laser beam joining of aluminium alloy to hot-dip galvanized (GI) steel sheets with Zn-15%Al filler wire. The authors reported the formation of phase layer thickness around 5 μm with joint strength of 190 ~ 230 N mm-1. A nearly similar filler wire composition was used by Dharmendra et al.18) to join 1.2 mm thick AA6016 alloy to 0.77 mm thick GI steel sheets following heat input range of 30 ~ 180 J mm-1. Fig. 1 shows that authors achieve maximum joint strength around 200 MPa for a heat input range of 60 ~ 110 J mm-1 by containing the phase layer thickness within 8 ~ 12 μm18). While, Shabadi et al.19) used a heat input of 45 J mm-1 to join 1.2 mm thick AA6016 alloy and 0.7 mm thick GI steel sheets by laser beam based process using Zn-30%Al filler wire. The phase layer thickness was found to be within 10 μm with maximum joint strength of 190 MPa19).
Fig. 1
Variation of heat input, joint strength and phase layer thickness in laser beam joining of aluminium alloy and steel sheets18). Heat input and joint strength are marked by circle and square, respectively
jwj-36-5-1f1.jpg
Other authors used Si-based filler wire to join aluminium and steel sheets using laser beam due to their wider availability and ease of use. Sierra et al.10) joined 1 mm thick AA6016 alloy to 1.2 mm thick GI steel sheet using a laser beam with AA4047 (Al-12%Si) filler wire considering a heat input range of 120 ~ 150 J mm-1. The authors found phase layer thickness around 2 μm and the maximum joint strength was 190 MPa10). While, Zhang et al.20) reported phase layer thickness in the range of 1.5 ~ 13 μm with the maximum joint strength of 162 MPa in joining of 1.15 mm thick AA6016 alloy and 1.2 mm thick GI sheets by AA4043 (Al-5%Si) filler wire using heat input range of 138 ~ 156 J mm-1. A similar filler wire composition was used by Qin et al.21,22) to join 1 mm thick AA6013 alloy and 2 mm thick GI steel sheets using a laser-GMA hybrid process. The phase layer thickness was restricted within 2 ~ 4 μm and maximum joint strength was found to be around 247 MPa21).
Saida et al.23) used the tandem laser beam process for joining of 1.2 mm thick AA6022 alloy and 0.8 mm thick GI and galvannealed (GA) steel sheets with AA4047 filler wire. The authors found maximum joint strength of 180 N mm-1 with phase layer thickness around 2 ~ 3 μm. Yang et al.24) used heat input of around 70 ~ 168 J mm-1 to join 2 mm thick AA5754 alloy and 1 mm thick galvanized DP980 steel sheets by diode laser beam using AA4047 filler wire. Fig. 2 shows variation of joint strength as a function of heat input. The authors reported poor joint strength of 118 N mm-1 at a low heat input of 70 J mm-1, which was attributed to inadequate wetting of filler deposit on steel surface. At a medium heat input of 120 J mm-1, the joint strength was improved to 220 N mm-1 due to enhancement of wettability of filler deposit on the steel surface, and maximum heat input of 168 J mm-1 resulted in formation of greater amount of brittle intermetallic compounds and consequently reduced the joint strength to 137 N mm-1. Sun et al.25,26) employed AA4043 filler wire to join 2.5 mm thick AA6061 alloy and electrogalvanized steel sheets by fiber laser beam in butt joint configuration. The authors reported to contain the phase layer thickness in the range of 1.8 ~ 6.2 μm with joint strength of 174.64 MPa25,26).
Fig. 2
Influence of heat input on joint strength in laser beam joining of AA5754 alloy and galvanized DP980 steel sheets24)
jwj-36-5-1f2.jpg
Thomy et al.11) used heat input range of 47 ~ 56 J mm-1 to join 1.15 mm thick AA6016 alloy and 1 mm thick DC05 galvanized steel sheets by laser-GMA hybrid source using AA4047 filler wire. The authors found phase layer thickness around 4 ~ 12 μm and the maximum joint strength of 180 MPa11). Gao et al.27) joined AA6061 alloy to AISI304 stainless steel, both of 2 mm thickness, using laser-CMT hybrid technique with AA4047 filler wire. The authors found that a heat input range of 80 ~ 110 J mm-1 could contain the phase layer thickness within the range of 3 ~ 6.5 μm with the maximum joint strength of 130 MPa27).
In contrast to the laser-GMA hybrid process, Yan et al.28) employed both continuous and pulsed mode dual laser beam for joining of 1.2 mm thick AA6111 alloy and 0.8 mm thick low carbon steel sheets without any filler wire, and found the layer thickness around 10 ❍m with the maximum joint strength of 128 MPa. In another study, Frank29) used a combined pulsed and continuous laser beam to join 1 mm thick aluminium alloy and 0.75 mm thick GI sheets in both lap and flange joint configurations by AA4043, AA4047 and Zn-12%Al filler wires. The author reported maximum joint strength in the range of 180 ~ 220 MPa with all three types of filler wires in both the lap and the flange configurations. Ma et al.30) attempted to join 1 mm thick AA6061 alloy and 0.8 mm thick galvanized DP590 steel using a two-pass laser beam technique without any filler wire. The authors could contain the phase layer thickness around 5 μm with maximum joint strength of 158 N mm-1. While, Windmann et al.31) used a Al-Si3-Mn filler wire to join both 1.5 mm thick AA6016 alloy and aluminized steel sheets considering a higher heat input range of 240 ~ 330 J mm-1. The maximum joint strength was reported to be 175 MPa for phase layer thickness of 2 ~ 7 μm31). In contrast, Borrisutthekul et al.32) reported wider range of heat input of 225 ~ 900 J mm-1 in laser beam lap joining of 1.6 mm thick AA6022 alloy to 1.2 mm thick steel sheets using different backing plates. Pardal et al.33) spot welded 1 mm thick AA6111 alloy and DC04 uncoated low carbon steel sheets using conduction mode defocused laser beam in lap joint geometry. The authors reported to contain layer thickness around 10 μm with maximum joint strength of 130 MPa. Huang et al.34) joined 2 mm thick 5A02 alloy and 1 mm thick GI steel sheets without any filler wire by laser-GTA hybrid process. The maximum joint strength was found to be around 163 MPa at phase layer thickness of 8.7 μm and corresponding heat input of 136.8 J mm-1. In another study, Cui et al.35) employed dual laser beam for joining low carbon steel and AA6061 alloy, both of 1.5 mm in thickness, without any filler wire. The authors reported the maximum joint strength of 110.6 N mm-1 with the separation distance between the laser beam as 1.5 mm and power distribution ratio as 0.6735). Table 1 shows the ranges of employed heat input, growth of phase layer thickness and achieved joint strength in joining of aluminium to steel sheet by laser beam based and laser - arc hybrid processes.
Table 1
The ranges of employed heat input, growth of phase layer thickness and achieved joint strength in joining of aluminium to steel by laser beam based and laser-arc hybrid joining processes
Process Al Alloy, tAl (mm) Steel, tst (mm) H.I (J mm-1) Filler wire dP (μm) Strength Reference
Laser AA6016, 1 GI, 1.2 102 ~ 150 AA4047 2 190 MPa Sierra et al.10)
Al alloy GI 50 ~ 60 Zn-15%Al 5 193 ~ 230 N mm-1 Mathieu et al.17)
AA6016, 1.2 GI, 0.77 60 ~ 110 Zn-15%Al 8 ~ 12 200 MPa Dharmendra et al.18)
AA6016, 1.2 GI, 0.7 45 Zn-30%Al 10 190 MPa Shabadi et al.19)
AA6016, 1.15 GI, 1.2 138 ~ 156 AA4043 1.5 ~ 13 162 MPa Zhang et al.20)
AA6022, 1.2 GI and GA, 0.8 - AA4047 2 ~ 3 180 N mm-1 Saida et al.23)
AA5754, 2 DP980, 1 70 ~ 168 AA4047 - 137 ~ 220 N mm-1 Yang et al.24)
AA6061, 2.5 Electro-GI, 2.5 - AA4043 1.8 ~ 6.2 174.64 MPa Sun et al.25,26)
AA6111, 1.2 Low carbon, 0.8 - - 10 128 MPa Yan et al.28)
Al alloy, 1 GI, 0.75 - AA4043, AA4047, Zn-12%Al - 180 ~220 MPa Frank29)
AA6061, 1 DP590, 0.8 - - 5 158 N mm-1 Ma et al.30)
AA6016, 1.5 Aluminized steel, 1.5 240 ~ 330 Al-Si3-Mn 2 ~ 7 175 MPa Windmann et al.31)
Laser-spot AA6111, 1 Uncoated DC04, 1 - - 10 130 MPa Pardal et al.33)
Laser-GMA hybrid AA6016, 1.15 DC05, 1 47 ~ 56 AA4047 4 ~ 12 180 MPa Thomy et al.11)
AA6013, 1 GI, 2 - - 2 ~ 4 247 MPa Qin et al.21,22)
AA6061, 2 AISI304, 2 80 ~ 110 AA4047 3 ~ 6.5 130 MPa Gao et al.27)
Laser-GTA hybrid 5A02, 2 GI, 1 136.8 - 8.7 136.8 Huang et al.34)

H.I - Heat input, dP - phase layer thickness, tAl - aluminium sheet thickness, tSt - steel sheet thickness

4. Gas Metal Arc Based Joining

Several researchers have attempted joining of aluminium and steel sheets using pulsed current GMA based process using Al-Si filler wires. Murakami et al.12) used a flux cored AA4047 filler wire to join 2 mm thick pure aluminium alloy and uncoated steel sheets using a heat input range of 170 ~ 255 J mm-1. The maximum joint strength was reported to be 80 MPa with phase layer thickness around 0.9 ~ 2.5 μm12). Park et al.36) used AC pulsed GMA process to join 1.4 mm thick uncoated steel and 1.6 mm thick AA6K21 alloy by AA4043 filler wire. The phase layer thickness was contained within 1.14 ~ 3.2 μm and the maximum joint strength was achieved as 173 MPa36).
Su et al.13,14) examined the effect of four different filler wires - pure aluminium, AA4043, AA4047 and AA5356 (Al-5%Mg) wire - to join AA5052 alloy and GI steel sheets, both in 1 mm thickness, using a AC double-pulsed GMA technique with heat input of 111 J mm-1. Pure aluminium and Al-Mg filler wires exhibited a constant phase layer thickness of around 30 μm14). The layer thickness reduced to 1 ~ 7 μm when Al-Si filler wires were used13,14). The joints made with the pure aluminium and Al-Mg filler wires exhibited lower failure strengths of respectively 165 and 112 MPa, and the same with the Si-based wires was around 201 MPa13,14). In another study, Shi et al.37,38) and Shao et al.39) used pulsed current double-electrode GMA technique to examine the effect of AA4043 and AA5356 filler wires in joining both of 1 mm thick AA5052 alloy and GI sheets. The maximum joint strength with the Al-Si filler wire was reported to be around 199 MPa37). The joints that were made with the Al-Mg filler wire had resulted in higher thickness of phase layer as compare to that achieved with the Al-Si filler wire and lower joint strength of 188 MPa37).
Several researchers also studied the effect of galvanized coating on the quality of pulsed current GMA based joining of aluminium alloys and coated steel sheets. Yagati et al.40) joined 2 mm thick AA6061 alloy and 1.2 mm thick GI, GA and uncoated steel sheets using a heat input of 62.75 J mm-1 with AA4043 filler wire. The joint strength with the GI sheets was reported around 180 N mm-1 as compared to 120 and 110 N mm-1 respectively with the GA and uncoated steel sheets40). The authors attributed the lower phase layer thickness and greater joint strength for the GI steel sheets due to the superior wetting on unmelted steel sheets40). While, Zhang and Liu15) studied joining of aluminium alloy to hot-dip aluminized and GI stainless steel sheets, all in 1 mm thickness, by pulsed current GMA technique using AA4043 filler wire with suitable ranges of heat input of 63 ~ 120 J mm-1. The aluminium to GI steel joints exhibited a continuous bead, whereas the aluminium and the aluminized steel sheets failed to produce any joint15). Fig. 3 shows variation of heat input and joint strength in GMA joining of aluminiu to GI sheets as reported in Ref. [15]. Fig. 3 illustrates joint strength is increasing from 168 to 194 MPa with an increase in heat input from 63 to 86 J mm-1. Further increase in heat input to 120 J mm-1 reduced strength to 169 MPa. The joints with the GI sheets exhibited phase layer thickness around 5 ~ 15 μm with maximum joint strength of 194 MPa, while layer thickness of 10 μm with failure strength of 60 MPa was found with the aluminized steel sheets15).
Fig. 3
Comparison of heat input and joint strength in GMA joining of aluminium to GI sheets15)
jwj-36-5-1f3.jpg
Zhang et al.41) used Cold Metal Transfer (CMT), a pulsed current GMA technique with short-circuiting metal transfer, to join 1 mm thick AA1060 and 0.6 mm thick GI sheets in lap joint configuration using AA4043 filer wire. Fig. 4 depicts the current and voltage transients in a typical CMT process as reported by the authors41). Following points are worth noting from Fig. 4,41).
Fig. 4
The current and voltage waveform of CMT process41)
jwj-36-5-1f4.jpg
  • The peak current phase is represented by a constant arc voltage and a high current pulse that was envisaged to facilitate the formation of a droplet at the tip of filler wire,

  • In the background phase, the current was reduced and kept constant till the beginning of the short-circuiting period to decrease the arc power and inhibit globular transfer of droplet from the filler wire tip,

  • During the short circuiting phase the filler wire dipped into the melt pool causing the arc to extinguish and the voltage reduced to zero. A backward movement of the filler wire at this stage is provided to assist the detachment of the droplet from the filler wire into the melt pool without the aid of electromagnetic force. The arc reignite at the end of short circuiting phase41).

The authors reported phase layer thickness around 4 μm with maximum joint strength of 83 MPa41). Agudo et al.5) used the CMT process to join 1 mm thick AA6016 alloy and hot dip galvanized steel sheets with AA1080 (Al~99.8%) filler wire and found phase layer thickness of 2.3 μm at the joint interface. In another study, Zhang et al.42,43) used AA4043 filler wire to join both of 1 mm thick aluminium alloy and GI sheets by the CMT process with a heat input range of around 55 ~ 91 J mm-1. The authors reported phase layer thickness around 7 ~ 40 ❍m and achieved the maximum joint strength of 96 MPa42,43). Cao et al.6) achieved a smooth joint bead in joining of AA6061 alloy and GI sheets, both in 1 mm thickness, using the CMT process with AA4043 filler wire and higher heat input of 200 J mm-1. The authors achieved maximum joint strength of 200 MPa by containing the phase layer thickness within 3 ~ 5 μm6). Kang and Kim44) employed typical heat input of 112 J mm-1 to join AA5052 alloy with hot dip aluminized and with GI steel sheets in the thickness ranges of 1 to 1.2 mm by CMT process using AA4043, AA4047, AA5183 and AA5356 filler wires. The authors found phase layer thickness around 5 μm with Al-Si filler wire while the Al-Mg filler wire resulted in higher the phase layer thickness of 12 ~ 13 μm44).
Das et al.7,45,46) used a wide range of heat input from 36 ~ 126 J mm-1 for joining of aluminium alloy to GI and GA steel sheets by coldArc, a low heat input pulsed current GMA process. Fig. 5 shows the current and voltage waveform of coldArc process and following points are noting7)
Fig. 5
Current and voltage waveform of coldArc process7)
jwj-36-5-1f5.jpg
  • The short-circuiting period (tS) began with rapid increase in welding current and drop of voltage to a very small value.

  • At the end of the short-circuiting period, the current was reduced to a small value to shear-off the molten metal from liquid bridge at a low power resulting in reduction of spatter.

  • In arcing period (tA), a peak current pulse was applied for a very short duration to facilitate the formation of droplet at the tip of filler wire. Current was reduced further and kept constant until the droplet formed a liquid bridge with molten pool.

The authors found a profound dependence of heat input with phase layer thickness and joint strength. Fig. 6 shows variation of phase layer thickness and joint strength with heat input in joining of AA5754 alloy and GI sheets. Fig. 6(a) shows phase layer thickness is increasing from 0.52 to 3.73 μm with rise in heat input from 36 to 68 J mm-1. Fig. 6(b) depicts an increase in heat input from 36 to 53 J mm-1 increases corresponding joint strength from 188 to 206 MPa, and further rise in heat input decreases joint strength to 180 MPa7). The authors found phase layer thickness around 1.3 ~ 2 ❍m with maximum joint strength of 73 MPa for aluminium to GA sheets45,46), while joining with GI sheet exhibited higher joint strength of 210 MPa with phase layer thickness of 0.8 ~ 4.5 ❍m7).
Fig. 6
Variation of heat input with (a) phase layer thickness and (b) joint strength in GMA joining of AA5754 alloy and GI sheets7)
jwj-36-5-1f6.jpg
Milani et al.47) examined the influence of different filler wires - AA4043, AA4047 and Al-Si3-Mn - on joining of 2 mm thick AA5754 alloy and 3 mm thick GI steel sheets by CMT process. The maximum joint strength was found to be around 188 MPa with the Al-Si3-Mn1 filler wire47). In another study, Chang et al.48) investigated the effect of AA2319 (Al-6%Cu) and AA5087 (Al-5%Mg) filler wire on joint quality in joining of AA6082 and ultra-high strength steel, both of 4 mm in thickness, by GMA process. The authors found Al-Cu filler wire exhibited lower phase layer thickness around 2 ~ 4 μm while Al-Mg filler wire resulted layer thickness of 6 ~ 18 μm48). The maximum joint strength was reported to be around 128 MPa using Al-Cu filler wire48).
Ma et al.49) employed different pre-heating temperature to join 1 mm thick AA5052 alloy and 2 mm thick GI sheet by pulsed current GMA process using heat input rage of 54.6 ~ 110.5 J mm-1 and AA4043 filler wire. The author reported pre-heating temperature had direct influence on growth of phase layer thickness. The authors found phase layer thickness in the range of 1 ~ 10 μm and achieved maximum joint strength around 162 MPa for pre-heat temperature of 373 K49). Madhavan et al.50) used heat input rage of 110 ~ 140 J mm-1 for joining 2 mm thick AA6061 alloy and 1.6 mm thick DP800 steel sheets by CMT process with AA4043 filler wire. The corresponding phase layer thickness and the maximum joint strength were reported to be 1.23 ~ 3.02 μm and 440 N mm-1, respectively50).
Ye et al.51,52) achieved excellent joint bead using GMA-GTA double sided arc process in joining AA5052 alloy and low carbon steel, both of 3 mm in thickness, with AA4043 filler wire and considering heat input of 85.8 J mm-1. The author found lower layer thickness of 2.03 μm using double sided arc process while conventional GMA process exhibited layer thickness of 4.03 μm. The maximum joint strength in double sided arc process was reported to be 148.1 MPa, which was 2.5 times than that of the traditional GMA process51). Table 2 illustrates a brief summary of heat input and flier wire composition on the joint strength and formation of intermetallic phase layer in GMA based joining of aluminium and steel sheets.
Table 2
Applied heat input, intermetallic phase layer thickness and corresponding joint strength in joining of aluminium to steel by GMA based joining process
Process Al Alloy, tAl (mm) Steel, tst (mm) H.I (J mm-1) Filler wire dP (μm) Strength Reference
Pulsed GMA Al alloy, 2 Uncoated steel, 2 170 ~ 255 AA4047 0.9 ~ 2.5 80 MPa Murakami et al.12)
Al alloy, 1 GI, 1 63 ~ 120 AA4043 5 ~ 15 168 ~ 194 MPa Zhang and Liu15)
AA5052, 1 GI, 1 - AA4043, AA5356 - 199 MPa (AA4043), 188 MPa (AA5356) Shi et al.37,38), Shao et al.39)
AA6061, 2 GI, GA and uncoated steel, 1.2 62.75 AA4043 - 110 ~ 180 N mm-1 Yagati et al.40)
AA6082, 4 UHSS, 4 - AA2319, AA5087 2 ~ 4 (AA2319), 6 ~ 18 (AA5087) 128 MPa (AA2319), 65 MPa (AA5087) Chang et al.48)
AA5052, 1 GI, 2 54.6 ~ 110.5 AA4043 1 ~ 10 162 MPa Ma et al.49)
AC pulsed GMA AA6021, 1.6 Uncoated steel, 1.4 - AA4043 1.14 ~ 3.2 173 MPa Park et al.36)
AC Double-pulsed GMA AA5052, 1 GI, 1 111 Pure Al AA4043, AA4047, AA5356 1 ~ 7 (AA4043, AA4047), ~ 30 (pure Al, AA5356) 112 MPa (AA5356), 165 MPa (Pure Al), 201 MPa (AA4043, AA4047) Su et al.13,14)
Double sided arc joining AA5052, 3 Low carbon steel, 3 85.8 AA4043 2.03 148.1 MPa Ye et al.51)
CMT AA6016, 1 GI, 1 - AA1080 2.3 - Agudo et al.5)
AA6061, 1 GI, 1 200 AA4043 3 ~ 5 200 MPa Cao et al.6)
AA1060, 1 GI, 0.6 - AA4043 4 83 MPa Zhang et al.41)
Al alloy, 1 GI, 1 55 ~ 91 AA4043 7 ~ 40 96 MPa Zhang et al.42,43)
AA5052, 1 Al-coated and GI, 1.2 111 AA4043, AA4047, AA5183, AA5356 5 (Al-Si filler), 12 ~ 13 (Al-Mg filler) 75 ~ 188 MPa Kang and Kim44)
AA5754, 2 GI, 3 - AA4043 AA4047, Al-Si3-Mn - 188 MPa Milani et al.47)
AA6061, 2 DP800, 1.6 110 ~ 140 AA4043 1.23 ~ 3.02 440 N mm-1 Madhavan et al.50)
coldArc AA5754 and AA5052, 1 ~ 1.5 GI and GA, 1 ~ 1.2 36 ~ 126 AA4043 0.8 ~ 4.5 210 MPa (GA), 73 MPa (GA) Das et al.7,45,46)

UHSS - ultra-high strength steel

Experimental investigations on joining of aluminium to steel sheets by laser beam, laser-arc hybrid and GMA based joining processes with different filler wire compositions are presented. The best joint strength could be achieved with a relatively thinner phase layer. The heat input and composition of filler wire were reported to be a crucial factor to control the growth of the phase layer. Furthermore, the Zn coating in case of galvanized sheets could improve the wetting of the filler wire deposit on the unmelted steel surface and the joint strength.

5. Influence of Heat Input on Intermetallic Phase Layer Thickness and Joint Strength

A direct effect of heat input on the formation of thicker phase layer is generally agreed in most of the experimental studies in joining of aluminium and steel using laser beam and GMA based processes. However, the suggested range of heat input for controlling the phase layer thicknesses also varied in the published literature. For example, a heat input range of 47 ~ 110 J mm-1 was reported to contain the phase layer thickness within 4 ~ 8 μm and resulted joint strength around 96 ~ 200 MPa in GMA15,41,42,49), laser beam18) and laser-arc hybrid11) joining of aluminium and steel with Al-Si11,15,41,42) and Zn-Al18) based filler wires. In contrast, typical phase layer thickness of 2 ~ 7 μm and corresponding joint strength around 200 MPa were reported for a heat input range of 111 ~ 150 J mm-1 in GMA,13,14,44) and laser beam10,20) joining of aluminium and steel with pure Al13), and Al-Si10,13,14,20,44) based filler wires. Even a higher heat input range of 170 ~ 330 J mm-1 resulted in typical phase layer thickness around 0.9 ~ 7 μm and joint strength around 80 ~ 200 MPa in GMA6,12) and laser beam31) based joining of aluminium and steel with Al-Si6,12,31) based filler wires. In contrast, a lower heat input range of 56 ~ 156 J mm-1 was found to result in the formation of thick layer of 12 ~ 20 μm and joint strength of 200 MPa in laser beam18,20) and laser-arc hybrid11) joining of aluminium and steel with Al-Si11,20) and Zn-Al18) based filler wires.

6. Influence of Filler Wires on Intermetallic Phase Layer Thickness and Joint Strength

In general, pure-Al, Al-Si, Zn-Al and Al-Mg based filler wires were employed to join aluminium and steel sheets by GMA, laser beam and laser-arc hybrid processes. The pure-Al based filler wires typically resulted in phase layer thickness in the range of 2.3 ~ 7 μm and joint strength around 165 MPa in GMA5,14) based joining techniques. The AA4043 filler wire formed layer thickness in the range of 1 ~ 20 μm and corresponding joint strength around 83 ~ 200 MPa in GMA6,7,13-15,36-39,41-43,49,51) and laser beam20,25) based joining processes. In contrast, AA4047 filler wire resulted in phase layer thickness in the range of 0.9 ~ 12 ❍m and joint strength around 80 ~ 200 MPa in GMA12-14,44), laser beam10,23) and laser-arc hybrid11,27) processes.
The Zn-Al based filler wires, resulted the phase layer thickness in the range of 5 ~ 12 μm and joint strength around 200 MPa in laser beam17-19) joining process. In contrast, AA5183 and AA5356 filler wires reported the growth of layer thickness around 7 ~ 13 μm and the joint strength of 112 ~ 188 MPa in GMA13,14,44) based processes. Influence of filler wire composition on intermetallic phase layer thickness and the final joint strength for laser beam and GMA based joining processes is presented in tabular form as Table 3.
Table 3
Filler wire composition on intermetallic phase layer thickness and the final joint strength for laser beam and GMA based joining processes
Filler wire dP (μm) Strength Process Reference
Pure Al 2.3 - CMT Agudo et al.5)
2 ~ 7 165 MPa AC double pulsed GMA Su et al.13,14)
AA4043 3 ~ 5 200 MPa CMT Cao et al.6)
0.8 ~ 4.5 210 MPa coldArc Das et al.7)
4 ~ 7 188 MPa AC double pulsed GMA Su et al.13,14)
5 ~ 15 194 MPa Pulsed GMA Zhang and Liu15)
1.14 ~ 3.2 173 MPa Pulsed GMA Park et al.36)
- 199 MPa Pulsed GMA Shi et al.37,38), Shao et al.39)
4 83 MPa CMT Zhang et al.41)
7 ~ 20 96 MPa CMT Zhang et al.42,43)
1 ~ 10 162 MPa CMT Ma et al.49)
2.03 148 MPa Double side arc joining Ye et al.51)
1.5 ~ 13 162 MPa Laser Zhang et al.20)
1.8 ~ 6.2 174.6 4 MPa Laser Sun et al.25)
AA4047 0.9 ~ 2.5 80 MPa Pulsed GMA Murakami et al.12)
1 ~ 4 201 MPa AC double pulsed GMA Su et al.13,14)
5 175 N mm-1 CMT Kang and Kim44)
2 190 MPa Laser Sierra et al.10)
2 ~ 3 180 N mm-1 Laser Saida et al.23)
4 ~ 12 180 MPa Laser - GMA hybrid Thomy et al.11)
3 ~ 6.5 130 MPa Laser - GMA hybrid Gao et al.27)
Zn-30%Al and Zn-15%Al 5 193 ~ 230 N mm-1 Laser Mathieu et al.17)
8 ~ 12 200 MPa Laser Dharmendra et al.18)
10 190 MPa Laser Shabadi et al.19)
AA5183 and AA5356 ~ 30 112 MPa AC double pulsed GMA Su et al.13,14)
12 ~ 13 188 MPa CMT Kang and Kim44)

7. Conclusion

A brief survey of the experimental studies on joining of aluminium and steel sheets using laser beam, laser - arc hybrid and GMA based techniques is presented in the above sections. The effect of joining processes such as heat input and filler wire composition on the joint strength and formation of intermetallic phase layer at the joint interface are analyzed in details. The experimental studies reported in the literature have shown that the heat input and filler wire composition would primarily influence the growth of phase layer at the joint interface and the final joint strength, irrespective of joining processes. However, the reported studies remained inconclusive about the permissible range of heat input to contain the phase layer thickness. Further, recent advancements in low energy pulsed current GMA techniques with controlled short-circuiting and metal transfer at low power have provided an opportunity to utilize these techniques for the joining of aluminium alloys and galvanized steels at a very low heat input.

Acknowledgement

The authors would like to thank Prof. Amitava De, IIT Bombay, Mumbai, India for his valuable ideas and suggestions to improve the contents of the present work.

References

1. U. Dilthey and L. Stein, Multimaterial car body design: challenge for welding and joining, Sci. Technol. Weld. Joi. 11(2) (2006) 135–142. https://doi.org/10.1179/174329306X85967
[CROSSREF] 
2. JE. Gould, Joining aluminum sheet in the automotive industry - a 30 year history, Weld. J. 91(1) (2012) 23s–34s.
3. WS. Miller, L. Zhuang, J. Bottema, AJ. Wittebrood, PD. Smet, A. Haszler, and A. Vieregge, Recent development in aluminium alloys for the automotive industry, Mater. Sci. Eng. A. 280(1) (2000) 37–49. https://doi.org/10.1016/S0921-5093(99)00653-X
[CROSSREF] 
4. HKDH. Bhadeshia, Problems in the welding of automotive alloys, Sci. Technol. Weld. Joi. 20(6) (2015) 451–453. https://doi.org/10.1179/15Z.000000000379
[CROSSREF] 
5. L. Agudo, D. Eyidi, CH. Schmaranzer, E. Arenholz, N. Jank, J. Bruckner, and AR. Pyzalla, Intermetallic FexAly-phases in a steel/Al-alloy fusion weld, J. Mater. Sci. 42(12) (2007) 4205–4214. https://doi.org/10.1007/s10853-006-0644-0
[CROSSREF] 
6. R. Cao, JH. Sun, JH. Chen, and P. Wang, Cold metal transfer joining of aluminum alloys-to-galvanized mild steel, J. Mater. Process. Tech. 213(10) (2013) 1753–1763. http://dx.doi.org/10.1016/j.jmatprotec.2013.04.004
[CROSSREF] 
7. A. Das, M. Shome, SF. Goecke, and A. De, Joining of aluminium alloy and galvanized steel using a controlled gas metal arc process, J. Manuf. Process. 27 (2017) 179–187. https://doi.org/10.1016/j.jmapro.2017.04.006
[CROSSREF] 
8. X. Sun, EV. Stephens, MA. Khaleel, H. Shao, and M. Kimchi, Resistance spot welding of aluminum alloy to steel with transition material - from process to performance - part I: experimental study, Weld. J. 83(7) (2004) 188s–195s.
9. T. Watanabe, H. Takayama, and A. Yanagisawa, Joining of aluminum alloy to steel by friction stir welding, J. Mater. Process. Tech. 178(1-3) (2006) 342–349. https://doi.org/10.1016/j.jmatprotec.2006.04.117
[CROSSREF] 
10. G. Sierra, P. Peyre, FD. Beaume, D. Stuart, and G. Fras, Steel to aluminium braze welding by laser process with Al-12Si filler wire, Sci. Technol. Weld. Joi. 13(5) (2008) 430–437. https://doi.org/10.1179/174329308X341852
[CROSSREF] 
11. C. Thomy and F. Vollertsen, Laser-MIG hybrid welding of aluminium to steel - effect of process parameters on joint properties, Weld. World. 56(5-6) (2012) 124–132. https://doi.org/10.1007/BF03321356
[CROSSREF] 
12. T. Murakami, K. Nakata, H. Tong, and M. Ushio, Dissimilar metal joining of aluminum to steel by MIG arc brazing using flux cored wire, ISIJ Int. 43(10) (2003) 1596–1602.
[CROSSREF] 
13. Y. Su, X. Hua, and Y. Wu, Effect of input current modes on intermetallic layer and mechanical property of aluminum-steel lap joint obtained by gas metal arc welding, Mater. Sci. Eng. A. 578 (2013) 340–345. https://doi.org/10.1016/j.msea.2013.04.097
[CROSSREF] 
14. Y. Su, X. Hua, and Y. Wu, Influence in alloy elements on microstructure and mechanical property of aluminum-steel lap joint made by gas metal arc welding, J. Mater. Process. Tech. 214(4) (2014) 750–755. https://doi.org/10.1016/j.jmatprotec.2013.11.022
[CROSSREF] 
15. H. Zhang and J. Liu, Microstructure characteristics and mechanical property of aluminum alloy/stainless steel lap joints fabricated by MIG welding-brazing process, Mater. Sci. Eng. A. 528(19-20) (2011) 6179–6185. https://doi.org/10.1016/j.msea.2011.04.039
[CROSSREF] 
16. I. Lum, S. Fukumoto, E. Biro, DR. Boomer, and Y. Zhou, Electrode pitting in resistance spot welding of aluminum alloy, (5182) Metall. Mater. Trans. A. 35(1) (2004) 217–226. https://doi.org/10.1007/s11661-004-0122-8
[CROSSREF] 
17. A. Mathieu, R. Shabadi, A. Deschamps, M. Suery, S. Mattei, D. Grevey, and E. Cicala, Dissimilar material joining using laser (aluminum to steel using zinc-based filler wire), Opt. Laser Technol. 39(3) (2007) 652–661. https://doi.org/10.1016/j.optlastec.2005.08.014
[CROSSREF] 
18. C. Dharmendra, KP. Rao, J. Wilden, and S. Reich, Study on laser welding-brazing of zinc coated steel to aluminum alloy with a zinc based filler, Mater. Sci. Eng. A. 528(3) (2011) 1497–1503. https://doi.org/10.1016/j.msea.2010.10.050
[CROSSREF] 
19. M. Shabadi, A. Suery, and A. Deschamps, Characterization of joints between aluminum and galvanized steel sheets, Metall. Mater. Trans. A. 44(6) (2013) 2672–2682. https://doi.org/10.1007/s11661-012-1605-7
[CROSSREF] 
20. MJ. Zhang, GY. Chen, Y. Zhang, and KR. Wu, Research on microstructure and mechanical properties of laser keyhole welding-brazing of automotive galvanized steel to aluminum alloy, Mater. Design. 45 (2013) 24–30. https://doi.org/10.1016/j.matdes.2012.09.023
[CROSSREF] 
21. GL. Qin, YH. Su, and SH. Wang, Microstructures and properties of welded joint of aluminum alloy to galvanized steel by Nd: YAG laser +MIG arc hybrid brazing-fusion welding, T. Nonferr. Metal Soc. 24(4) (2014) 989–995. https://doi.org/10.1016/S1003-6326(14)63153-8
[CROSSREF] 
22. G. Qin, L. Zhen, Y. Su, B. Fu, X. Meng, and S. Lin, Large spot laser assisted GMA brazing-fusion welding of aluminum alloy to galvanized steel, J. Mater. Process. Tech. 214(11) (2014) 2684–2692. https://doi.org/10.1016/j.jmatprotec.2014.06.011
[CROSSREF] 
23. K. Saida, H. Ohnishi, and K. Nishimoto, Fluxless laser brazing of aluminium alloy to galvanized steel using a tandem beam - dissimilar laser brazing of aluminium alloy and steels, Weld. Int. 24(3) (2010) 161–168. https://doi.org/10.1080/09507110902843065
[CROSSREF] 
24. J. Yang, Y. Li, H. Zhang, W. Guo, D. Weckman, and N. Zhou, Dissimilar laser welding/brazing of 5754 aluminum alloy to DP 980 steel: mechanical properties and interfacial microstructure, Metall. Mater. Trans. A. 46(11) (2015) 5149–5157. https://doi.org/10.1007/s11661-015-3079-x
[CROSSREF] 
25. J. Sun, J. Huang, Q. Yan, and Z. Li, Fiber laser butt joining of aluminum to steel using welding - brazing method, Int. J. Adv. Manuf. Tech. 85(9-12) (2015) 2639–2650. https://doi.org/10.1007/s00170-015-8137-4
[CROSSREF]  [PDF]
26. J. Sun, Q. Yan, W. Gao, and J. Huang, Investigation of laser welding on butt joints of Al/steel dissimilar materials, Mater. Design. 83 (2015) 120–128. https://doi.org/10.1016/j.matdes.2015.05.069
[CROSSREF] 
27. M. Gao, C. Chen, S. Mei, L. Wang, and X. Zeng, Parameter optimization and mechanism of laser - arc hybrid welding of dissimilar Al alloy and stainless steel, Int. J. Adv. Manuf. Tech. 74(1-4) (2014) 199–208. https://doi.org/10.1007/s00170-014-5996-z
[CROSSREF] 
28. S. Yan, Z. Hong, T. Watanabe, and T. Jingguo, CW/PW dual-beam YAG laser welding of steel/aluminum alloy sheet, Opt. Laser. Eng. 48(7-8) (2010) 732–736. https://doi.org/10.1016/j.optlaseng.2010.03.015
[CROSSREF] 
29. S. Frank, Flux-free laser joining of aluminum and galvanized steel, J. Mater. Process. Tech. 222 (2015) 365–372. https://doi.org/10.1016/j.jmatprotec.2015.03.032
[CROSSREF] 
30. J. Ma, M. Harooni, B. Carlson, and R. Kovacevic, Dissimilar joining of galvanized high-strength steel to aluminum alloy in a zero-gap lap joint configuration by two-pass laser welding, Mater. Design. 58 (2014) 390–401. https://doi.org/10.1016/j.matdes.2014.01.046
[CROSSREF] 
31. M. Windmann, A. Rottger, H. Kugler, W. Theisen, and F. Vollertsen, Laser beam welding of aluminum to Al-base coated high-strength steel 22MnB5, J. Mater. Process. Tech. 217 (2015) 88–95. https://doi.org/10.1016/j.jmatprotec.2014.10.026
[CROSSREF] 
32. R. Borrisutthekul, T. Yachi, Y. Miyashita, and Y. Mutoh, Suppression of intermetallic reaction layer formation by controlling heat flow in dissimilar joining of steel and aluminium alloy, Mater. Sci. Eng. A. 467(1-2) (2007) 108–113. https://doi.org/10.1016/j.msea.2007.03.049
[CROSSREF] 
33. G. Pardal, S. Meco, S. Ganguly, S. Williams, and P. Prangnell, Dissimilar metal laser spot joining of steel to aluminium in conduction mode, Int. J. Adv. Manuf. Tech. 73(1-4) (2014) 365–373. https://doi.org/10.1007/s00170-014-5802-y
[CROSSREF] 
34. J. Huang, J. He, X. Yu, C. Li, and D. Fan, The study of mechanical strength for fusion-brazed butt joint between aluminum alloy and galvanized steel by arc-assisted laser welding, J. Manuf. Process. 25 (2017) 123–133. http://dx.doi.org/10.1016/j.jmapro.2016.11.014
[CROSSREF] 
35. L. Cui, B. Chen, L. Chen, and D. He, Dual beam laser keyhole welding of steel/aluminum lapped joints, J. Mater. Process. Tech. 256 (2018) 87–97.
[CROSSREF] 
36. HJ. Park, S. Rhee, MJ. Kang, and DC. Kim, Joining of steel to aluminum alloy by AC pulse MIG welding, Mater. Trans. 50(9) (2009) 2314–2317. http://dx.doi.org/10.2320/matertrans.M2009105
[CROSSREF] 
37. Y. Shi, L. Shao, J. Huang, and Y. Gu, Effects of Si and Mg elements on the microstructure of aluminum - steel joints produced by pulsed DE-GMA welding / brazing, Mater. Sci. Tech. 29(9) (2013) 1188–1124. https://doi.org/10.1179/1743284713Y.0000000291
[CROSSREF] 
38. Y. Shi, G. Zhang, Y. Huang, L. Lu, J. Hunag, and Y. Shao, Pulsed double-electrode GMAW-brazing for joining of aluminum to steel, Weld. J. 93(6) (2014) 216s–224s.
39. L. Shao, Y. Shi, JK. Huang, and SJ. Wu, Effect of joining parameters on microstructure of dissimilar metal joints between aluminum and galvanized steel, Mater. Design. 66(B) (2015) 453–458. https://doi.org/10.1016/j.matdes.2014.06.026
[CROSSREF] 
40. KP. Yagati, RN. Bathe, KV. Raajulapati, KBS. Rao, and G. Padmanabham, Fluxless arc weld-brazing of aluminium alloy to steel, J. Mater. Process. Tech. 214(12) (2014) 2949–2959. https://doi.org/10.1016/j.jmatprotec.2014.06.017
[CROSSREF] 
41. HT. Zhang, JC. Feng, P. He, BB. Zhang, JM. Chen, and L. Wang, The arc characteristics and metal transfer behaviour of cold metal transfer and its use in joining aluminium to zinc-coated steel, Mater. Sci. Eng. A. (499) (1-2) (2009) 111–113. https://doi.org/10.1016/j.msea.2007.11.124
[CROSSREF] 
42. HT. Zhang, JC. Feng, P. He, and H. Hackl, Interfacial microstructure and mechanical properties of aluminium-zinc-coated steel joints made by a modified metal inert gas welding-brazing process, Mater. Charact. 58 (2007) 588–592. https://doi.org/10.1016/j.matchar.2006.07.008
[CROSSREF] 
43. HT. Zhang, JC. Feng, and P. He, Interfacial phenomena of cold metal transfer (CMT) welding of zinc coated steel and wrought aluminium, Mater. Sci. Tech. 24(11) (2008) 1346–1349. https://doi.org/10.1179/174328407X213152
[CROSSREF] 
44. M. Kang and C. Kim, Joining Al 5052 alloy to aluminized steel sheet using cold metal transfer process, Mater. Design. 81 (2015) 95–103. https://doi.org/10.1016/j.matdes.2015.05.035
[CROSSREF] 
45. A. Das, M. Shome, CR. Das, SF. Goecke, and A. De, Joining of galvannealed steel and aluminium alloy using controlled short circuiting gas metal arc welding process, Sci. Technol. Weld. Joi. 20(5) (2015) 402–408. https://doi.org/10.1179/1362171815Y.0000000032
[CROSSREF] 
46. A. Das, M. Shome, SF. Goecke, and A. De, Numerical modelling of gas metal arc joining of aluminium alloy and galvanized steels in lap joint configuration, Sci. Technol. Weld. Joi. 21(4) (2016) 303–309. https://doi.org/10.1080/13621718.2015.1104206
[CROSSREF] 
47. AM. Milani, M. Paider, A. Khodabandeh, and S. Nategh, Influence of filler wire and wire feed speed on metallurgical and mechanical properties of MIG welding - brazing of automotive galvanized steel/5754 aluminum alloy in a lap joint configuration, Int. J. Adv. Manuf. Tech. 82(9-12) (2016) 1495–1506. https://doi.org/10.1007/s00170-015-7505-4
[CROSSREF]  [PDF]
48. Q. Chang, D. Sun, X. Gu, and H. Li, Microstructures and mechanical properties of metal inert-gas arc welded joints of aluminum alloy and ultrahigh strength steel using Al - Mg and Al - Cu fillers, J. Mater. Res. 32(3) (2017) 1–11. https://doi.org/10.1557/jmr.2016.487
[CROSSREF] 
49. H. Ma, G. Qin, X. Bai, L. Wang, and Z. Liang, Effect of initial temperature on joint of aluminum alloy to galvanized steel welded by MIG arc brazing-fusion welding process, Int. J. Adv. Manuf. Tech. 86(9-12) (2016) 3135–3143. https://doi.org/10.1007/s00170-016-8425-7
[CROSSREF]  [PDF]
50. S. Madhavan, M. Kamaraj, L. Vijayaraghavan, and KS. Rao, Microstructure and mechanical properties of aluminium/steel dissimilar weldments: effect of heat input, Mater. Sci. Tech. 33(2) (2017) 200–209. https://doi.org/10.1080/02670836.2016.1176716
[CROSSREF] 
51. Z. Ye, J. Huang, W. Gao, Y. Zhang, Z. Cheng, S. Chen, and J. Yang, Microstructure and mechanical properties of 5052 aluminum alloy/mild steel butt joint achieved by MIG-TIG double-sided arc welding-brazing, Mater. Design. 123 (2017) 69–79. https://doi.org/10.1016/j.matdes.2017.03.039
[CROSSREF] 
52. Z. Ye, J. Huang, Z. Cheng, L. Xie, Y. Zhang, S. Chen, and J. Yang, Study on butt joining 5052 aluminum alloy/ Q235 mild steel by MIG-TIG double-sided arc welding-brazing process, Weld. World. 62(1) (2018) 145–154. https://doi.org/10.1007/s40194-017-0516-z
[CROSSREF]  [PDF]


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