1. Introduction
Submerged arc welding (SAW) is applied in the welding of thick steel plates in heavy engineering industries such as shipbuilding and pressure vessel construction [
1]. In the SAW process, electrical and chemical parameters are combined to form an arc between the weld wire tip and the steel base plate. Raw unmelted flux and molten flux (slag) cover the arc to form the arc cavity. Weld wire and flux are continuously fed through the welding head arrangement as it moves along the weld. In the arc cavity the molten weld wire metal droplets are transferred into the weld pool as complex physical and chemical interactions of heat and mass transfer occur [
1]. Chemical reactions continue in the trailing molten weld pool of molten flux and steel, until the steel is solidified as weld metal [
2,
3]. Flux typically contains a mixture of various oxides and fluorides, and the latter is usually added as CaF
2. An important empirically determined flux composition guideline is to ensure that the flux basicity index (BI), expressed in Equation (1), exceeds 1.5 to ensure low hydrogen and low total oxygen content in the weld metal [
4,
5].
It is well established that an excessive quantity of oxygen is initially added to the molten weld wire droplets from the arc cavity gas phase, up to 2000–3000 ppm O [
6,
7]. This initial oxygen quantity in the metal droplets is sourced from the decomposition of less stable oxides at the high temperatures prevailing in the plasma arc, and so flux chemistry is used to manage oxygen transfer to the weld metal from the plasma arc [
8]. The plasma arc stability of oxides was determined in welding tests made with binary CaF
2-oxide flux mixtures, from high to low stability: CaO, K
2O, Na
2O and TiO
2, Al
2O
3, MgO, SiO
2, and MnO [
8]. Therefore, increased addition of CaF
2 to the flux will dilute the quantity of low stability oxides in the flux to ensure lower ppm O in the weld metal. Weld metal oxygen must be controlled within a relatively narrow band to ensure high weld metal impact toughness. Both too low (<200 ppm O) and too high (>500 ppm) weld metal oxygen contents were found to be detrimental to weld metal impact toughness [
9].
Previous work confirmed that the excess oxygen transferred from the arc cavity reacts with the molten steel at the plasma-weld pool interface to form FeO. This FeO ends up in the molten flux. The correlation of increased FeO in the molten flux with increased weld metal ppm O is well known [
10,
11,
12,
13,
14,
15]. In our previous work we illustrated the use of metal powders (Ti and Al) to control the oxygen potential at the flux-weld pool interface, as presented by the quantity of FeO in the molten flux, to meet the requirements of sufficient ppm O in the weld metal and increased Ti content in the weld metal [
16].
Ti-oxide inclusions form active nucleation sites for acicular ferrite (AF) microstructure formation in the weld metal to improve weld metal strength and toughness [
17,
18]. Furthermore, it has been established that increased Ti content (from 30 ppm to 1300 ppm Ti) in the weld metal increases AF formation by changing Ti-oxide inclusion chemistry [
19]. When TiO
2 is increased in the SAW flux to increase Ti in the weld metal, only a limited quantity of Ti (310 ppm Ti) is transferred to the weld metal [
20,
21]. Increased weld metal Ti content of 700 ppm was reported in gas shielded fluxed cored arc welding [
22]. In this work we use copper metal powder, in addition to the Ti and Al metal powder, as used in our previous study, to improve the transfer of Ti and Al into the weld pool. The application of unconstrained (not fluxed cored wire) metal powders in SAW is well illustrated as applied to increasing welding productivity in welding joint applications, and in cladding applications [
23,
24,
25]. However, limited published studies were reported on the application of unconstrained metal powders to generate a highly alloyed weld metal joint in SAW. Knowledge on the behaviour of the different alloying elements in the SAW process in terms of interaction with oxygen and added powder alloy elements will provide better process development choices to attain efficient alloying from the metal powders.
Copper is added in small quantities (0.32% Cu) to high-strength low-alloy steel to enhance AF formation associated with Al-Ti-oxide inclusions, and thus improve the weld metal impact toughness [
26]. Higher copper addition levels are used in carbon steels, and additions of up to 4% Cu are made to chrome-manganese stainless steels to improve steel corrosion resistance and still maintain good weldability [
27]. Limited work has been done on welding of high-entropy alloys (HEAs) and compositionally complex alloys (CCAs), [
28]. Therefore, a method for welding HEA plates by generating a closely matched weld metal composition is an important milestone for utilizing HEAs and CCAs in manufacturing. Due to SAW being a high productivity welding method, this method should be included in such work. This approach ties in with our current study since increased attempts are made to use Cu in HEA design. For example, the expensive Co in the Al
xCoCrFeNi alloy may be replaced with inexpensive Cu [
29]. However, the addition of copper to weld wire causes work hardening of the weld wire so that the wire is not easily formed, or easily used as feed wire material in the welding process [
30]. From the above discussion it is clear that copper may find different materials property applications in different steel and alloy grades and in the welding of these material grades. Furthermore, copper feed in the form of metal powder offers a solution to the practical materials problem of feeding work hardening copper containing wire. The purpose of this work is to illustrate the application of copper metal powder addition in SAW to stabilise the Al and Ti powder metal uptake into the weld metal, and still control the ppm O in the weld metal within the target of 200–500 ppm O.
2. Materials and Methods
Welding experiments were conducted with and without metal powders (Al, Ti, and Cu) to illustrate the process concept of oxygen potential control at the molten flux-weld pool interface in the presence of Cu.
SAW welding tests were made as bead-on-plate runs onto steel plates of 350 mm length, 12 mm plate thickness and 300 mm plate width. Weld heat input was 2.0 kJ/mm (500 A, 28 V, 42 cm/minute) welded DCEP (Direct Current Electrode Positive) with 3.2 mm diameter wire. Structural steel grade EN 10025-2 was used as base plate material. The weld wire major element levels are from the supplier’s specification sheet as supplied by Afrox Ltd., South-Africa. The rest of the element analyses in
Table 1 were obtained from laboratory analyses. The base plate steel was analysed by optical emission spectroscopy (OES). The oxygen content in the base plate and weld wire was analysed by combustion method.
The welded plate was sectioned to remove cross section samples of the weld metal for major element analyses by OES, and total oxygen content analyses by combustion method. Due to higher concentrations of Ti and Al in the weld metal, compared to low carbon steel, Al and Ti contents were analysed by ICP-OES (Inductively coupled plasma optical emission spectrometry). A Zeiss crossbeam 540 FEG (Field emission gun) SEM (scanning electron microscope) was used in this study. EDS (energy dispersive spectrometer) analyses were done at 20 kV and 5.6 mm working distance.
Commercial agglomerated flux of composition in
Table 2 was used in the welding experiments. This is an Aluminate Basic flux (Basicity Index (BI) = 1.4) and was extensively analysed as reported previously [
31]. The metal powder additions were sourced as Al (99.7% Al) supplied by Sigma-Aldrich, Ti (99.5% Ti) supplied by PLS Technik GmbH & Co. and Cu (99.8% Cu) supplied by Goodfellow.
3. Results
The weld metal compositions for the three scenarios, weld metal formed without metal powder addition as the Base Case (BC), weld metal formed with 10 g Al and 10 g Ti metal powder addition (MP1), and weld metal formed with 10 g Al, 10 g Ti and 10 g Cu metal powder addition (MP3), are summarised in
Table 3.
Comparison of the BC and MP weld metal analyses in
Table 3 clearly shows increased levels of Si, Mn, Al, and Ti in the MP1 and increased Cu in the MP3 weld metal due to added metal powders used in SAW. The ppm O in the BC and MP1 welds are similar at 499 ppm without powder additions and 509 ppm with Al and Ti powder additions. However, when Cu is also added to the weld (MP3) the weld metal ppm O is lowered to 371 ppm O.
SEM micrographs and EDS analyses were used to confirm increased Ti content in the weld metal for MP1 and MP3. The MP1 EDS analyses were already described previously [
16]. Similarly, the EDS analyses results for the MP3 weld metal analyses areas in
Figure 1, as displayed in
Table 4, correspond well to the bulk weld metal analyses in
Table 3. MnO and SiO
2 were reduced by Al powder according to reactions (2) and (3). Similarly, FeO is reduced from the molten flux via reaction (4).
Increased Si and Mn content in the MP1 and MP3 weld metal, compared to the BC weld metal, confirms that sufficient contact time was established between Al powder and molten flux to enable reactions (2) and (3) to proceed forward. The Al2O3 products formed in these two reactions most likely ended up in the molten flux since the reactions occurred at the molten flux-weld pool interface. Most importantly, sufficiently reducing conditions were maintained in the presence of Al powder to dissolve large quantities of Ti powder in the weld pool, and not oxidise all the Ti powder to Ti-oxides at the molten flux-weld pool interface. The ppm O quantities in the MP1 and MP3 weld metal analyses are too small in proportion to the weld metal Ti content for all Ti to be present in the form of oxides. Therefore, oxide inclusion formation preference is expected to be set by the thermodynamic likelihood of reactions between the steel elements Al, Ti, Si, Mn, and oxygen in the weld pool steel.
4. Discussion
The lowered ppm O and increased Al content in the MP3 weld metal, in association with added Cu powder, indicates a modification in the reactions due to Cu powder addition. The melting point of pure Al, Ti and Cu are 660 °C, 1660 °C and 1083 °C. Clearly from the weld metal analyses in
Table 3, more metal powder was added into the MP3 weld metal, in the presence of Cu, than was added into the MP1 weld metal. The mass quantities of Ti and Al added to the weld metals MP3 and MP1 are calculated in the following section.
From each welding test, the mass of metal added to the weld plate was recorded. For each weld metal cross section, the areas above and below the base plate level were measured to determine the dilution ratio, namely the mass proportions of (wire + metal powder) vs. base plate contributed to the weld metal. The dilution ratio percentage (
%DR(wire+MP)) is expressed in Equation (5). The mass of Al, Ti, and Cu added to the weld metal was calculated from Equations (5) to (7), using the weld metal composition in
Table 3 as input to Equation (7). Equation (7) is expressed for the Al mass added, but similar calculations were made for Ti and Cu using the weld metal composition in
Table 3.
WM, weld metal; MP, metal powder; BP, base plate; Wire, weld wire; m, mass (gram); A, area (mm
2)
The mass of metal powders incorporated into the weld metal are summarised in
Table 5, in addition to the mass values of the total weld metal, base plate and wire. Although the mass of Ti melted into the weld metal is similar for MP1 and MP3 weld metal, the mass of Al melted into the MP3 weld metal is higher, and the total mass of metal powders melted into the MP3 weld metal is significantly higher at 12.8 grams vs. 5.5 grams melted into MP1. This effect of increased metal powder incorporation into the weld metal for the same welding energy input is due to the metal stabiliser role of copper as set out in the following discussion.
The binary alloy phase diagrams displayed in
Figure 2,
Figure 3 and
Figure 4 were taken from the FactSage 7.3 thermochemical software documentation to illustrate the chemical effect of Cu [
32]. The stabiliser effect by Cu is due to its extensive lowering of the Ti liquidus temperature from 1660 °C to as low as 1265 °C at the mol ratio of Ti/(Cu+Ti) = 0.65 at the red arrow in
Figure 2. This mol ratio corresponds approximately to that of the MP3 alloy composition in
Table 3. The Cu metal powder added to the weld pool serve as stabiliser of Ti in the weld pool by decreasing the temperature required to melt Ti into the weld pool.
The Cu-Fe and Cu-Al phase diagrams in
Figure 3 and
Figure 4 indicate only a slight liquidus lowering effect of small quantities of copper added to Fe or Al. Cu does not have a high affinity for oxygen, as compared to Al, and therefore remains in the weld pool as a metal to perform its role of lowering the Ti metal powder liquidus temperature. Furthermore, once the weld pool is formed, the cooling time of the weld pool may be extended if the weld pool steel chemistry has a lowered solidus temperature. This appears to be the case as displayed in
Figure 5 as the solidification curve for MP3 weld metal shows the solidus temperature as 1311 °C, compared to the solidus temperature of MP1 weld metal at 1363 °C. These curves were calculated in the Equilib module of FactSage 7.3, using the FToxid and FSstel databases [
32].
Increased silicon and manganese content in the MP weld metal analyses in
Table 3, as compared to the BC weld metal, confirms that SiO
2 and MnO were reduced from the molten flux by the added Al powder. The mass of Mn and Si added to the MP weld metals, relative to the BC weld metal nominal composition, was calculated from the weld metal mass and the dilution ratio values in
Table 5, as illustrated in Equation (8) for Mn. The mass of Si added relative to the BC value may be calculated by using the %Si values, instead of the %Mn values, in Equation (8). The square bracketed terms of Equation (8) represent the calculation of the BC weld metal nominal composition.
The mass of SiO
2 and MnO reduced from the flux by Al powder via reactions (2) and (3) are summarised in
Table 6. These values are the mass values of Mn and Si calculated from Equation (8), expressed as the oxides MnO and SiO
2. The kJ heat generated from each reduction reaction as calculated from the exothermic reaction heat values (ΔH
2000°C) displayed next to reactions (2) and (3) are also summarised in
Table 6. The exothermic heat quantity values are expressed as weld metal temperature increase values by using the heat capacity of steel (0.460 kJ/kg K). These values for MP1 and MP3 weld metal are similar, at −5.3 kJ and −4.5 kJ exothermic heat evolved, potentially heating the weld metal by 112 °C and 107 °C, respectively. These are minimum values since the extent of reaction (4) is not known, and this reaction definitely proceeded in part since reaction (4) is used to control the partial oxygen pressure at the weld pool-slag interface [
16]. Since the same welding parameters and the same welding flux was used it is expected that the same quantity of oxygen was initially present in the weld pool, as transferred via the weld wire metal droplets from the arc cavity.
The importance of the similar numbers in
Table 6 is that the difference in melting rate of metal powders into MP1 and MP3 weld metal is unlikely due to different extents of the exothermic reactions of Al/SiO
2 and/or Al/MnO as displayed in reactions (2) and (3). Since the same weld heat input settings of V, A and travel speed were applied in all the tests, the time taken for the weld pool to solidify should be the same if the weld pool compositions were similar [
33]. From the differences in weld metal ppm O in MP1 at 509 ppm O vs. 371 ppm O in MP3, it appears that the weld pool solidification time was longer in the case of Al-Ti-Cu powder additions, as compared to only Al-Ti powder additions. The added copper lowers the alloy steel solidus temperature (as illustrated in
Figure 5) and so increases the time available for oxide inclusions to float out of the weld pool liquid steel to the molten flux-weld pool interface, where the inclusions are then incorporated into the molten flux.
Therefore, our initial SAW reaction flow diagram as illustrated previously, is updated as shown in
Figure 6 to include the stabiliser behaviour of copper metal powder [
16]. The reaction flow diagram in
Figure 6 illustrates the reaction sites and reaction sequence in the SAW process. Reaction steps A to E are as presented from previous works as reported in literature. Al powder added to the weld pool serves to control the oxygen potential at the molten flux-weld pool interface by reducing FeO via reaction (4) in the text, which is similar to reaction G in
Figure 6. These reduction reactions are exothermic and release heat from chemical energy into the weld pool to further facilitate melting and dissolution of Ti.
Despite the added Al and Ti powder in the weld pool, the weld metal oxygen content remained relatively high at 509 ppm O in MP1 and 371 ppm O in MP3 weld metal. The addition of copper powder does not appear to influence the weld metal oxygen content via chemical reactions since copper has a low affinity for oxygen. As concluded in our previous study, in the presence of Al and Ti metal powders, the weld metal oxygen content is not set by equilibrium de-oxidation reactions in the weld pool since the quantity of dissolved oxygen, captured as inclusions in the solid weld metal, was much higher than the Al-Al
2O
3 and Ti-Ti
2O
3 de-oxidation reaction equilibrium values of 10 ppm O at 0.1% Al and 30 ppm O at 4% Ti in steel at 1600 °C [
34]. Gas-slag-metal equilibrium has been illustrated to hold for SAW in the absence of metal powders as discussed elsewhere [
10,
35].
The same mechanism of oxygen transfer from the arc cavity to the weld pool appears to hold for both instances, Al and Ti powder added in MP1 and Al and Ti powder in combination with Cu powder addition in MP3, since the ppm O in the MP1 and MP3 weld metal is much higher than would be set by Al-Al2O3 and Ti-Ti2O3 de-oxidation reaction equilibria. The reduced oxygen potential at the molten flux-weld pool interface prevents oxidation of Ti powder to Ti-oxides, and ensures that the Ti is melted with Cu and then dissolved into the weld pool, reaction I. Since there is an excess of Al added, some of the Al also dissolves into the weld pool (reaction H). Both dissolved Ti and Al react with oxygen in the steel to form inclusions (reaction F). Reactions I and J illustrate the role of Cu as stabiliser whereby Cu first forms a low temperature alloy with Ti to decrease the temperature required for melting Ti into the weld pool.
The results presented here confirm that the oxygen potential at the molten flux-weld pool interface is sufficiently controlled by Al powder addition, even when Cu powder is added to the weld pool. The lowered oxygen potential at the molten flux-weld pool interface enhances Ti powder transfer into the weld pool, without interfering with oxygen transfer from the plasma arc to the weld pool. Copper metal powder addition to the weld pool acts as a stabiliser metal by lowering the Ti liquidus temperature from 1660 °C to as low as 1265 °C. The copper metal powder added to the weld pool serves as stabiliser of Ti in the weld pool by decreasing the temperature required for melting Ti into the weld pool.