Designed Al-Si-Cu-Ni-Sr alloys were prepared by using commercially pure Al, Al-50 wt.% Si, Al-50 wt.% Cu, Al-20 wt.% Ni and Al-10 wt.% Sr. Those alloys were melted and mixed in an electric resistance furnace to achieve the desired compositions which were verified by an Inductively-Coupled Plasma Atomic Emission Spectrometer based on ASTM E1479-99. The melt was kept at 730˚C ± 10˚C for 30 minutes for the completion of homogenization and modification under the protective gas of nitrogen, and then the melt temperature was decreased to 650˚C for squeeze casting.

Specimens were sectioned, mounted, and polished from the center of the squeeze disk and prepared following the standard metallographic procedures. A Buehler (Lake Bluff, IL) optical image analyzer 2002 system was used to observe primary characteristics of the specimens. The detailed features of the microstructure were also characterized at high magnifications by a scanning electron microscope (SEM). To maximize composition reading of the energy dispersive spectroscopy (EDS) data, an etchant of 0.5% NaOH solution was applied to polished specimens for microscopic examination.

The mechanical properties of the squeeze cast Al-6Si-3Cu alloys and Al-6Si-3Cu-0.03Sr-0.5Ni alloys were evaluated by tensile testing, which was performed at ambient temperature on an MTS criterion Tensile Test Machine (Model 43) equipped with a data acquisition system. Following ASTM B557, flat tensile specimens (25 mm in gage length, 6 mm in width, and 4 mm in thickness) were machined from the squeeze cast discs. The tensile properties, including ultimate tensile strength (UTS), and 0.2% yield strength (YS) were obtained based on the average of three tests.

The electrical conductivity is an important electrical property of the squeeze cast alloys. The handhold device SIGMASCOPE with FS40 probe was employed the electrical conductivity measurements of the squeeze cast alloys based on the phase sensitive eddy current method. This type of signal evaluation enables non-contact measurement. It also minimizes the influence of surface roughness. The measuring range of the device is 0.5% - 108% IACS (% International Annealed Copper Standard), and the accuracy at room temperature is ±0.5% of the measured reading. The electrical conductivity data were obtained based on the average of three tests.

For alloy chemistry design, based on the literature survey, four alloying element, Si, Cu, Ni and Sr, were chosen with three levels and are listed in Table 1. The experimental layout for the four factors using L9 orthogonal array is given in Table 2. Two sets of the Taguchi experiments were conducted to ensure the reliability of experimental data for signal-to noise analysis.

In the alloy design process, it is almost impossible to eliminate all errors caused by the variation of characteristics. An increase in the variance of multiple characteristics lowers the quality reliability of the process. The Taguchi method [11] [12] uses the signal-to-noise (S/N) ratio instead of the average value to interpret the trial results data into a value for the characteristic evaluation in the optimum setting analysis. To minimize the influence of the error caused by the variation of

characteristics, the signal-to-noise (S/N) ratio was employed, which converted the trail result data into a value for the response to evaluate the process in the optimum setting analysis. The S/N ratio consolidated several repetitions into one value which reflected the amount of variation present. This is because the S/N ratio can reflect both the average and the variation of the quality characteristics. In the present study, the mechanical and electrical properties of the designed alloys were treated as a characteristic value. Since the mechanical and electrical properties of the novel alloys were intended to be maximized, the S/N ratio for higher is best (HB) characteristics was selected and calculated as follows:

S/N HB = − 10 log ( 1 n ∑ i = 1 n 1 η p i 2 ) (1)

where n is the repetition number of each experiment under the same condition for design parameters, and η p i is the property of an individual measurement at the ith test. After calculating and plotting the mean S/N ratios at each level for various factors, the optimal level, that was the largest S/N ratio among all levels of the factors, was determined.

The objective function was formulated according to the proposition for the optimization of mechanical and electrical properties with multiple performance characteristics (three objectives) by a weighting method:

Maximaze   f ( X ) = W 1 ⋅ η U T S + W 2 ⋅ η σ + W 3 ⋅ η Y S (2)

where η U T S is the S/N ratio of the ultimate tensile strength, η σ is the S/N ratio of the electrical conductivity, η Y S is the S/N ratio of the yield strength, and w₁, w₂, and w₃ are the weighting factor of the S/N ratio for the ultimate tensile strength, electrical conductivity and yield strength, respectively.

The above objective function is presented in an analytical form as a function of input parameters since ultimate tensile strength, yield strength and electrical conductivity as three characteristics are important properties for cast components in induction motor. The three characters should be considered as different critical roles by weighting factors. For induction motor in the electrical vehicle, the strength and electrical conductivity are equally important in engineering applications. For cast components of which strengths have a priority higher than the other mechanical properties, such as ductility, higher weighting factors of ultimate tensile strength and yield strength need to be considered. However, the cast components in the induction motor desired both higher strengths, enhanced electrical conductivity, and improved castability for high-performance applications including automobile parts. As an example, in this study, for high strengths and electrical conductivity application, combination of weighting factor as 0.2:0.6:0.2 is selected to demonstrate the optimization of strength and electrical conductivity. The combinations of weighting factors may vary for various application and engineering requirements.

The purpose of the analysis of variance is to investigate the contribution of each factor (chemical element) with multiple characteristics that significantly affect the mechanical properties and electrical conductivity. Following the analysis, it is relatively easy to identify the effect order of factors on strengths and electrical conductivity, and the contribution of factors to strengths and electrical conductivity. In this study, variation due to both the four factors and the possible error was taken into consideration. The ANOVA was established based on the sum of the square (SS), the degree of freedom (D), the variance (V), and the percentage of the contribution to the total variation (P). The five parameters symbol typically used in ANOVA are described below:

1) Sum of Squares (SS). SS_P denotes the sum of squares of factors A, B, C, and D; SS_e denotes the error sum of squares; SS_T denotes the total sum of squares.

The total sum of square SS_T from S/N ratio was calculated as:

S S T = ∑ i = 1 m η 2 i − 1 m [ ∑ i = 1 m η i ] 2 (3)

where m is the total number of the experiments, and η_i is the factor response at the i_th test.

The sum of squares from the tested factors, SS_p, was calculated as:

S S P = ∑ i = 1 m ( S η j c ) 2 t − 1 m [ ∑ i = 1 m η i ] 2 (4)

where m is the number of the tests (m = 9), j the level number of this specific factor p, t is the repetition of each level of the factor p, and S_ηj the sum of the multi-response S/N ratio involving this factor p and level j.

2) Degree of Freedom (D). D denotes the number of independent variables. The degree of freedom for each factor (D_P) is the number of its levels minus one. The total degrees of freedom (D_T) are the number of total numbers of the result data points minus one, i.e., the total number of trials times the number of repetitions minus one. The degree of freedom for the error (D_e) is the number of the total degrees of freedom minus the total of degree of freedom for each factor.

3) Variance (V). Variance is defined as the sum of squares of each trial sum result involved the factor, divided by the degrees of freedom of the factor:

V p ( % ) = S S p D p × 100 (5)

4) The Corrected Sum of Squares (SS_p). SS_p is defined as the sum of squares of factors minus the error variance times the degree of freedom of each factor:

S S p ' = S S p − D p V e (6)

5) Percentage of the contribution to the total variation (P). P_p denotes the percentage of the total variance of each individual factor:

P p ( % ) = S S p ' S S p × 100 (7)

To comprehensively evaluate the engineering performance of lightweight Al alloys for electrically conductive applications, the optimization criteria for rotor bars in electric motors were defined as material capabilities of resisting plastic deformation and fracture effectively, and conducting electric current efficiently. The yield strength (YS) is the stress an alloy can withstand without plastic deformation, while the ultimate tensile strength (UTS) is the maximum stress that an alloy can withstand before fracture [13]. The ability of an alloy to conduct electric current is represented by the electrical conductivity (σ) [14]. Hence, these three characteristics, UTS, YS and σ, were selected as multiple performance objectives for evaluating the designed alloys for the optimization. The experimentally determined UTS, YS and electrical conductivities are listed in Table 3.

Since the objectives, i.e., UTS, YS and σ, were intended to be maximized, the S/N ratio for HB (higher-is-best) characteristics was used [11]. The S/N ratios of these tensile properties and electrical conductivity were given in Table 4. The multi-responses of the S/N ratios using three weighting factor combinations were also concluded in Table 4. The three-weighting factors were w₁ = 0.2, w₂ = 0.6 and w₃ = 0.2 for UTS, σ and YS, respectively. The response of each factor to its individual level was calculated by averaging the S/N ratios of all the experiments at each level for each factor. With three combinations of three weighting factors, the mean multi-response S/N ratios of the factors for each level were calculated and summarized in Table 5, respectively. For instance, the mean S/N ratio (35.33) for Sr addition at level 2 in Table 5 with the weighting factors of w₁ = 0.2, w₂ = 0.6 and w₃ = 0.2 was the average value of the S/N ratios of experiment No.2 (35.55), No.4 (35.27) and No.9 (35.18) which were listed in Table 4.

As high strength and high electrical conductivity are mutually exclusive for metallic materials, the balance between strength and conductivity is essential to the design optimization of as-cast Al alloys for electrically conductive applications [15]. To optimize the strengths and electrical conductivities of the designed alloys for the rotor bars in the electric motors, the order of the performance characteristics was given as electrical conductivity (w₂ = 0.6), ultimate tensile strength (w₁ = 0.2), and yield strength (w₃ = 0.2). Figure 1 depicts the multi-response S/N ratios for the certain case of strength and electrical conductivity optimization.

As shown in Figure 1, the mean S/N ratio for factor A of Si addition continuously decreased with the amount of Si from 6 wt.% (level 1) to 12 wt.% (level 3). Since Si is a semiconductor, when a high amount of Si was introduced to the alloy, the electrical conductivity of the alloy decreased. The effect of the Cu addition (factor B) on the mean S/N ratio of the mechanical properties and electrical conductivity was also plotted in Figure 1. When Cu increased from 3 wt.% (level 1) to 5 wt.% (level 2), the mean multi-response S/N ratio of tensile properties and electrical conductivity decreased from 35.49 to 35.35. The ratio showed almost no increase to 35.39 (+0.11%), as Cu rose to 7 wt.% (level 3). This might be because sufficient Cu addition could form a large amount of the strengthening Al-Cu intermetallic phase and fine grain structure, which increased ultimate tensile strengths and yield strengths [16]. For Sr addition, as increasing from levels 1 to 2, the S/N ratio decreased slightly. Further addition of Sr led to an increase in the S/N ratio. This observation suggested that the presence of a high level of Sr benefited both the strengths and conductivity of the designed alloys. This is because Sr is a good modifier for silicon in Al alloys. An appreciable amount of Sr changed the morphology of eutectic silicon to spherical appearance in the microstructure, which increased the strengths of the alloys [17]. Examination of the effect of Ni addition (factor D) revealed that the multi-response S/N ratios including the electrical conductivity and tensile properties decreased, as the amount of Ni addition increased. As the maximum solubility of Ni in Al is very low (0.24 wt.%) [18], the introduction of relatively high Ni levels over 0.5 wt.% led to form massive Ni-containing intermatellics present not only at the boundaries of the primary a-Al dendrites but also inside them. Although the Al-Ni intermetallics in the microstructure enhanced the strengths of the Al-Si-Cu alloys, their presence in the primary a-Al phase impeded the electron movement and reduced the electrical conductivity [15] [19]. It revealed that the low level of Ni was desired for the designed alloys. By selecting the highest value of the mean S/N ratio for each factor, the optimal levels were determined, which were A1B1C3D1; i.e. 6 wt.% Si, 3 wt.% Cu, 0.03 wt.% Sr and 0.5 wt.% Ni.

The contribution of each factor to the tensile properties and electrical conductivity was determined by performing the analysis of variance (ANOVA) based on Equations (3)-(7). The results of analysis of variance for case: w₁ = 0.2, w₂ = 0.6 and w₃ = 0.2, are summarized in Table 6.

Table 6 lists the contribution of the four factors (Si, Cu, Sr and Ni addition) in case: w₁ = 0.2, w₂ = 0.6 and w₃ = 0.2, in which the electrical conductivity has a priority, was 40.58%, 22.84%, 19.52%, and 17.05%, respectively. The addition of Si had the highest contribution of 40.58%, which indicated that Si had the major influence on the electrical conductivity of the designed alloys. Cu (22.84%) and Sr (19.52%) were ranked as the second and third highest contributors which had a very close contribution to each other. The Ni had the lowest contribution of 17.05%.

As discussed above, the designed factors and levels of A1B1C3D1 were selected as the optimal combination for maximizing the ultimate tensile strength, electrical conductivity and yield strength (w₁ = 0.2, w₂ = 0.6 and w₃ = 0.2). The optimal alloy composition was 6 wt.% Si, 3 wt.% Cu, 0.03 wt.% Sr and 0.5 wt.% Ni. To confirm the optimal combination from the DOE based on the Taguchi method, a confirmation experiment of squeeze casting of the optimal alloy was conducted. Two individual tests were performed to obtain the objectives, UTS, σ and YS, are listed in Table 7. The results from the confirmation experiment given in Table 8 showed that the confirmed alloy had an averaged UTS of 247.58 MPa, an averaged electrical conductivity is 38.01%IACS, and an averaged yield strength of 143.47 MPa.

Figure 2 presents the microstructure of the optimized alloy obtained from the confirmation experiment. The analysis by the optical microscopy (Figure 2) showed that the microstructure consisted of the primary α-Al dendrite, eutectic silicon phase and intermetallic phases surrounding the α-Al phase. The element analysis indicates that the microstructure of the etched optimal alloy consists of primary a-Al, eutectic Si, the Al-Cu intermetallic phase and Al-Cu-Ni intermetallic phase. Figure 3 and Figure 4 present the SEM micrograph and EDS spectra of the optimal alloy squeezed cast in the confirmation experiment. Examination of the detailed features of the microstructure characterized by SEM and EDS analyses on the etched specimen revealed the intermetallic containing Cu and Ni. The addition of Ni facilitated the formation of the Ni-containing intermetallic phase. Also, it can be seen from Figure 3(a) that the addition of Sr refined the morphology of eutectic silicon, which was in a fibrous and globular shape. At high magnification, the SEM and EDS analyses identified the nano-sized particles of eutectic silicon, primary a-Al, the Al-Cu intermetallic phase and Al-Cu-Ni intermetallic phase in the optimal alloy, as illustrated in Figure 3(b) and 4. The significant improvement of the tensile properties and electrical conductivity should be attributed to the modification of eutectic silicon phase by addition of Sr and the presence of increased intermetallic content by the introduction of Ni. Fang [20] observed the similar strengthening effect in the squeeze cast Al-Si-Cu-Ni alloys.