Mechanical Characteristics of 6063 Aluminum-Steel Dust Composite

Studies on the effect of steel dust (EAF dust) addition on the mechanical properties of 6063 Aluminium alloy have been carried out. The cast composite samples contain steel dust from 2–20 wt% produced in sand mould. These cast samples were homogenized, cold rolled, and solution-treated. The solution treated samples were normalized in still air, some quenched in water while some were tempered after quenching. Tensile and hardness responses were determined in all these processed samples. The results obtained reveal that 10 wt% steel dust in aluminium 6063 improved the ultimate tensile strength to 111.09 MPa and a corresponding hardness of 51.2 HV. Microstructural analysis shows iron containing intermetallics which are well distributed in the matrix with its morphology depending on the heat treatment and deformation imposed on them. Tensile strength and hardness of the composites was also found to depend on the volume fraction of intermetallics in the matrix.


Introduction
Aluminum alloys find extensive usage in engineering applications due to its high specific strength (strength/density).These alloys are basically used in applications requiring lightweight materials, such as aerospace and automobiles.The 6xxx-group alloys have a widespread application, especially in the building, aircraft, and automotive industry due to their excellent properties [1][2][3].The 6xxx series contain Si and Mg as main alloying elements.These alloying elements are partly dissolved in the primary α-Al matrix, and partly present in the form of intermetallic phases.A range of different intermetallic phases may form during solidification, depending on alloy composition and solidification condition.Relative volume fraction, chemical composition, and morphology of structural constituents exert significant influence on their useful properties [4][5][6][7][8][9][10][11][12].
Previous research on the improvement of mechanical properties has been focused on heat treatment, precipitation, and age hardening [7][8][9][10][11][12][13]. Authors have noted that the formation and precipitation of intermetallics such as Al-Fe-Si and Al-Fe-Si-Mn have significant influence on the useful properties of 6xxx group of alloys if controlled [8][9][10][11][12].Other research has also focused on the addition of elements and particles to the 6xxx matrix in order to improve its mechanical properties.
Khraisat and Jadayil [14] studied the effect of strengthening aluminium scrap using iron powder in order to achieve better mechanical properties.Superior properties were observed in cast aluminium with 1 wt.% iron addition.The mechanical behaviour of an alloy based on Fe-40Al prepared from mechanically alloyed powders was examined over a wide temperature range in the fine-grained, as-extruded state as well as after recrystallization by Morris and Gunther [15].The study revealed that fine-grained material possesses improved strength and reasonable ductility at room temperature, in contrast with the weaker and more brittle largegrained material.However, at high temperature, the strength of both materials dropped.Sasaki et al. [16] characterized consolidated nanocrystalline Al-5 wt.% Fe alloy powders produced by mechanical alloying using spark plasma sintering.The sintered sample showed high strength with a large plastic strain of 15% at room temperature.Singh [17] also studied the peculiarities of aluminium-iron ore in-situ particulate composites.The strength and hardness values for the composites showed considerable improvement over the values for other composites.Darvishi et al. [18] examined the effect of iron and manganese concentration on the morphology of complex intermetallics and their influence on the mechanical properties and microstructure of Al-16.67 wt.% Si alloy using 0.4, 1.2, 1.8 wt.% iron contents and manganese contents of 0.6 and 0.9 wt.%.The results of UTS show that when iron increases, the UTS steadily decreases from 229 MPa of 0.4 wt.% of iron to 187 MPa when iron content reaches 1.8 wt.%.But the hardness increased from 104 to 130 HV as iron content increased from 0.4 to 1.8 wt.%.Orozco-Gonzàlez et al. [3] also examined the effect of iron addition on the structure of intermetallics formed in Al alloys.The study shows that for Al-Fe-Mn-Si alloys with Fe/Mn weight ratios up to 4, the α-phase had cubic crystal structure, while for alloys with Fe/Mn weight ratio of 5.3 or more, the α-phase had hexagonal crystal structure.The tensile behaviour of composites produced by infiltrating ceramic particle in Al matrix has been studied as a function of reinforcement size and chemistry (Al 2 O 3 and B 4 C) [19].An earlier research on the use of ceramic particles was conducted by Shih-Chang and Sinn-Wen [20].Both authors reported strengthening due to the reinforcements.Silicon carbide has also been used as reinforcement to strengthen Al alloys [21].Mechanical properties of Dispersion-strengthened-cast aluminium (DSC-Al-Sc(-Zr)) alloys containing two distinct populations of dislocation impeding particles: a high volume fraction of submicron, incoherent Al 2 O 3 dispersoids and a low volume fraction of nanometer-size, coherent Al 3 Sc precipitates, have also been examined [22].Results showed that the alloy exhibits strengthening at ambient temperature from both the Al 3 Sc precipitates and the Al 2 O 3 dispersoids, as measured by microhardness and uniaxial compressive testing.This paper examines the mechanical responses of aluminium alloy infiltrated with steel dust particles.
Thousands of tons of electric arc furnace (EAF) dust are generated in metallurgical plants each year.These dusts are waste and dumped considering environmental regulations.They are not easily disposed since they are considered toxic because it contains small amounts of Pb, As, and Cr oxides which are formed at high temperatures above the steel bath and in the off-gas systems.Overall, EAF dusts contain major elements of the type iron, zinc, calcium, manganese, magnesium, and silicon in the form of simple or mixed oxides.Spectrometric analysis of steel dust shows that it contains considerable amount of iron, manganese, and silicon in oxide form.These oxides when added to aluminium may serve as microadditions and being in oxide form may lead to improved properties of the 6xxx series alloys.The purpose of this research, therefore, is to experimentally investigate the effect of addition of the EAF dust on the mechanical properties of 6063 Al alloy.

Experimental Methodology
The AA6063 aluminum alloy used in this study was provided by Nigerian Aluminum Extrusion Company (NIGALEX), Oshodi, Lagos, with chemical composition given in Table 1.Steel dust, used for reinforcement in the aluminium alloy was obtained from Universal Steel Company, Ogba, Ikeja, Nigeria.The apparatus used in the melting, casting process, Billets of AA6063 aluminium alloy were cut and charged into a diesel-fired crucible furnace, melted at 700 • C and cast into cylindrical form in a metal mould.The melted aluminium alloy was mixed with steel dust in proportions of 2, 5, 10, 15, 20 wt.% to obtain the batches of the composite cast samples.The composite charge was now brought out with the help of long metal tongs, stirred with an iron rod to skim off slag suspensions, poured into the mould, and was left to solidify.After about 1 hour the solidified cast was removed, cleaned and homogenised at 520 • C for 2 hours in the box-type furnace.These homogenized composite samples were given 20% thickness reduction at ambient temperature (31 • C) in a 2-high rolling mill leaving some as control.All samples were grouped for further processing as shown below.
A Leco microhardness tester LM 700AT machine was used for the Rockwell hardness of the samples.Tensile test of samples was carried out using Testomeric AXM500-25 KN (Testomeric UK) machine.All tests were conducted according to ASTM E8 specification.Metallographic examination was carried out on each sample after the surfaces were ground, polished using a mixture of alumina etched in a solution containing 1 gram sodium hydroxide in 100 mLs of water for 20 secs.The prepared sample surfaces was dried in still air and the morphology of the samples were then examined with a digital metallurgical microscope at ×200 magnification.The photomicrographs of the composite samples morphologies are shown in Figures 5-8.

Mechanical Properties.
The results of the mechanical properties are shown in Figures 1-4.These figures give a summary of the ultimate tensile strength (UTS), Rockwell hardness number, and percentage elongation as a function of the percentage addition of steel dust.Figure 1 shows the variation of ultimate tensile strengths (UTS) with percent volume of steel dust in the aluminium.The UTS of the homogenized composite sample increases as the addition of steel dust increases to a peak value of 111 MPa at wt.10% steel dust addition.Further increase in steel dust addition resulted in a decline in the UTS to 70 MPa reached at 20 wt.% steel dust.For the SHRN and SHRQ composite samples the trend in UTS variation with percentage composition of dust is comparable to that of SH sample with maximum UTS of 108 MPa and 102 MPa, respectively, at 10 wt.% steel dust addition.The UTS declines as more steel dust is added in both processed sample groups.Tempered samples showed appreciable increase in the UTS as the wt.% steel dust addition increases to a peak value (124 MPa) at 15 wt.% steel dust and thereafter declines (Tables 3, 4, and 5).
The Rockwell hardness values of the aluminium-steel dust composite are shown in Figure 2.But for the SHRN sample, increase in the percentage steel dust addition was accompanied with corresponding increase in the hardness values and it reached a maximum value of 86 HRC at 15% after which the hardness value declines.Hardness of homogenized and SHRQ samples increased to a maximum value of 51.2 HRC and 47.4 HRC, respectively, at 10 wt.% of steel dust in the aluminium alloy.The tempered composite samples have 54.1 HRC at 5 wt.% steel dust and 47.7 HRC at 15 wt.% steel dust.
The strain values of the aluminium-steel dust composite are shown in Figures 3 and 4. Both strain at fracture and strain at ultimate tensile strength show appreciable response to normalizing and quenching treatments.Strain values were higher for these treatments (SHRN and SHRQ see Figures 3  and 4) than for any other treatment in all cases.Strain rises to maximum at 15 wt.% steel dust addition for both SHRN (35%) and SHRQ (36%) after which it declines.spherical crystals of Al 12 (Fe,Mn) 3 Si phase are not strongly precipitated as in "a" while the weight fraction of Al 5 FeSi phase is substantial in the matrix.In the SHRQ (Figure 5(c)) sample, the plate-like phase is absent.Spherical crystals of Al 12 (Fe,Mn) 3 Si phase are sparsely distributed and clustering of Mg 2 Si crystals is pronounced in this matrix.In the SHRT sample, the matrix contain crystals of Mg 2 Si phase that are finely distributed, with few spherical crystals of Al 12 (Fe,Mn) 3 Si phase.The plate-like crystals of Al 5 FeSi phase are fairly distributed in the matrix.

Discussion
The results of adding steel dust powder to 6063 aluminium alloy indicate marked effect on the tensile strength, ductility, and hardness properties of the alloy.The UTS result of these processed samples show significant improvement over the conventional 6063 aluminium alloy.This can be attributed to the combined effect of grain refinement propelled by increase in iron content and the formation, precipitation, and distribution of hard intermetallic compounds (Al 12 (Fe,Mn) 3 Si) at the grain boundaries of the Al alloy during solidification [4,12,14,23].
It is evident from the results that heat treatment processes aside mere homogenization do not impart any marked improvement on the mechanical properties of the material composite samples.This could be attributed to the fact that during homogenization an otherwise perfect structure is formed with the intermetallics well distributed to obtain optimum properties such that further treatment (cold rolling, normalizing, quenching, etc.) will only lead to a distortion of the otherwise perfect structure.This is evident from Figure 7(b) which shows that the smallsized crystals of (Al 12 (Fe,Mn) 3 Si) intermetallics are found evenly distributed in Figure 7(a) and were redistributed with crystal clustering and crystal coarsening as a result of the rolling and subsequent normalizing processes.SH samples showed superior tensile properties compared to all other samples subjected to further treatments.This is evident from the microstructure of the homogenized samples in Figures 5(a It is observed from the mechanical properties of SH samples that increase in the amount of steel dust leads to increase in UTS (Figure 1) attaining a peak value at 10 wt.% steel dust addition after which the UTS decreases.The strength of the material increases initially due to the increase in the amount of iron in the composition which led to grain refinement and subsequent precipitation of hard intermetallics.This trend is also seen in the work of Khraisat and Abu Jadayil [14].During casting of 6063 aluminium alloys a wide variety of Fecontaining intermetallics such as Al-Fe, Al-Fe-Si, and Al-Fe-Mn-Si phases are formed between the aluminium [12,23].The process of the alpha Al 12 (Fe,Mn) 3 Si phase formation is controlled by chemical composition of the alloy, but in the case of the nonequilibrium conditions the local fluctuations of the Fe, Mn, and Si concentrations decide the precipitation course [24].Tables 1 and 2 indicate that the amount of Fe, Mn, and Si will increase as the percentage of the steel dust in aluminium alloy increases due to their presence in the steel dust.However, the increase in Fe content can cause distinct growth in volume fraction of alpha-Al 12 (Fe,Mn) 3 Si phase particles (because of the very low solubility of these elements in Al) with changes in its morphology and size depending on the Fe : Mn ratio [24].As the volume fraction of iron formed intermetallics increases in the matrix, the UTS becomes lower.The reason that iron-containing intermetallic particles are detrimental to mechanical properties could be because they are hard and are therefore much more easily fractured under the tensile load than the aluminium matrix, the tendency increasing as the amount of the intermetallics increases.This agrees with the work of Darvishi et al. [18] who reported that the UTS of Al-16.6Sialloy decrease with a higher amount iron.
The effect of steel dust on the microhardness of aluminium alloys showed that as dust levels increase from 0 to 10 wt.%, the hardness of Al-Si-based alloys increases (see Figure 2) for SH samples but decrease afterwards.The microhardness values for SHRN, SHRQ, and SHRT samples have no specific trend.The effect of steel dust on hardness can be described by the size and volume fraction of ironcontaining intermetallics (particularly alpha Al 12 (Fe,Mn) 3 Si) which increased with iron content.However, as steel dust increases, iron level increases giving rise to increase in porosity (compare Figures 7(a Results also show that ductility of the Al-Si-based alloy was influenced by the amount of steel dust addition.Though no specific trend in the variation of strain with wt.% steel dust addition could be noticed (see Figures 3 and 4), it could be observed that the steel dust addition has a significant effect on the strain values.Normalized (SHRN) and quenched (SHRQ) samples had maximum strain values compared to any other treatment.During normalizing, the homogenized material is allowed to cool in still air allowing crystal coarsening and clustering.This is evident from Figure 7(b) which shows the small sized crystals of (Al 12 (Fe,Mn) 3 Si) intermetallics which were evenly distributed in Figure 7(a), redistributed with crystal clustering and coarsening as a result of the rolling and subsequent normalizing processes.During quenching (SHRQ) crystal growth is minimized.However, precipitation of Al 5 FeSi occurs in the matrix in small volume fraction (see Figure 7(c)) which supports ductility.These results are in support of the findings of Sasaki et al. [25] and Zajac et al. [26] who explained that the Al 5 FeSi crystals when they are round and in small volume fraction support elongation.

Conclusion
The effect of steel dust addition on the mechanical properties of 6063 Aluminium alloy has been studied.It was observed that there was considerable improvement in the mechanical
) and 8(a)) and which affect significantly the hardness responses of the aluminium composite samples.

Table 2 :
Spectrometric analysis of EAF steel dust.

Table 3 :
Variation of ultimate tensile strength values with wt.% steel dust addition.

Table 4 :
Variation of strain (at UTS) values with % steel dust addition.

Table 5 :
Variation of hardness values with % steel dust.