X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... 739–746 MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY BY CONTROLLING DIRECTIONAL SOLIDIFICATION PARAMETERS RAZVOJ MIKROSTRUKTURE IN SPREMEMBA LASTNOSTI ZLITINE Al-Si-Cu S KONTROLIRANJEM PARAMETROV DIREKTNEGA STRJEVANJA Xiaojie Yi 1 , Tao He 1,* , Yuanming Huo 1 , Shoushuang Chen 2 , Yajun Xu 1 , Abdou Yahouza Mahamane Sani 1 1 School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, no. 333 Longteng Road, Shanghai 201620, China 2 Chinese Academy of Social Sciences, Institute of Quantitative & Technical Economics, 5 Jianguomennei Street, Beijing 100732, China Prejem rokopisa – received: 2019-03-09; sprejem za objavo – accepted for publication: 2019-04-24 doi:10.17222/mit.2019.051 As the properties of the Al-Si-Cu alloy depend on the microstructure, it is necessary to study the effects of processing parame- ters on the microstructure to control the properties of the Al-Si-Cu alloy. A novel Al-Si-Cu alloy rod was prepared using direc- tional solidification (DS) of liquid metal cooling and the Al-Si-Cu alloy rod was investigated by using a scanning electron mi- croscope (SEM), a JVJ–50s test machine, a MHVD–1000IS microhardness tester and a FT300 resistivity tester. The SEM was used to capture micrographs. The JVJ–50s test machine was employed to measure stress-strain relationships. The MHVD–1000IS microhardness tester was used to measure the microhardness of the specimens. The FT300 resistivity tester was used to evaluate the electrical conductivity. Experimental results indicate that the dendrite structure of the microstructure can be refined by increasing the melting temperatures during DS, but the exorbitant temperature would make the precipitated phase coarsen. It was found that when the melting temperature was 750 °C and the pulling rate was 300 μm·s –1 , the maximum tension strength and microhardness were 232 MPa and 102 HV, respectively. Moreover, when the vacuum was 0.4 × 10 –3 MPa, the elec- trical properties of the alloy are the best, i.e., the minimum resistivity was 17.6 μ ·mm. Therefore, a set of optimum processing parameters, i.e., the melting temperature of 750 °C, the pulling rate of 300 μm·s –1 and the vacuum of 0.4 × 10 –3 MPa, can be se- lected to improve the microstructure and properties of the Al-Si-Cu alloy. Keywords: directional solidification, Al-Si-Cu alloy, microstructure, mechanical properties, electrical resistivity Lastnosti Al-Si-Cu zlitin so mo~no odvisne od mikrostrukture. Zato je za nadzor njihovih lastnosti potrebno raziskati u~inek procesnih parametrov na formiranje njihove mikrostrukture. Avtorji so sintetizirali novo zlitino na osnovi Al-Si-Cu s postopkom direktnega strjevanja (DS) raztaljene kovine. Ohlajene palice zlitine Al-Si-Cu izbrane kemijske sestave so preiskovali s pomo~jo metalografskih metod z uporabo vrsti~nega elektronskega mikroskopa (SEM), trgalnega stroja JVJ–50s, merilnika mikrotrdote MHVD–1000IS, in merilnika elektri~ne upornosti FT300. SEM so uporabili za izdelavo metalografskih posnetkov. S pomo~jo JVJ–50s stroja so izdelali krivulje odvisnosti med napetostjo in deformacijo. Z merilnikom mikrotrdote MHVD–1000IS so dolo~ili mikrotrdoto vzorcev sintetizirane zlitine. Z merilnikom FT300 pa so dolo~ili njihovo elektri~no upornost. Eksperimen- talni rezultati preiskav so pokazali, da je dendritno mikrostrukturo mo`no rafinirati (udrobiti) z vi{anjem temperature pregretja nad tali{~e zlitine med DS. Toda pretirano povi{evanje temperature pregretja lahko vodi do nastanka grobih izlo~kov sekundarne faze. Avtorji ugotavljajo, da so pri temperaturi pregretja 750 °C in hitrosti vle~enja strjene palice iz taline 300 μm·s –1 , dosegli maksimalno natezno trdnost 232 MPa in mikrotrdoto zlitine 102 HV. Nadalje ugotavljajo, da so pri vakuumiranju na podtlak 0,4 ×1 0 –3 MPa dosegli najbolj{e elektri~ne lastnosti zlitine z najmanj{o elektri~no upornostjo 17,6 μ ·mm. Tako so dolo~ili skupino optimalnih procesnih parametrov, in sicer temperaturo pregretja pri 750 °C, hitrosti vle~enja 300 μm·s –1 in vakuum 0,4 ×10 –3 MPa. Na ta na~in so lahko izbolj{ali mikrostrukturo in lastnosti izbrane Al-Si-Cu zlitine. Klju~ne besede: direktno strjevanje, zlitina Al-Si-Cu, mikrostruktura, mehanske lastnosti, elektri~na upornost 1 INTRODUCTION Aluminum alloys are widely used in the fields of aerospace, ships and automobiles. 1 The Al-Si-Cu alloy is one of the most popular cast aluminum alloys, which not only has good casting properties, but also has the advan- tages of low density, good corrosion resistance, small linear expansion coefficient, high strength and micro- hardness, good wear resistance and heat resistance, etc. 2,3 However, with the development of advanced manufactur- ing technology, the comprehensive mechanical properties of Al-Si-Cu alloys need to be further improved to meet the requirements of modern mechanical structures. A lot of research has been done on improving the properties of Al-Si-Cu alloys. Similarly, some publi- cations focused on the improvement of properties of Al-Si-Cu alloys by adding Mg, 4 rare-earth elements 5 and trace elements and changing the heat-treatment process and different casting forming processes includes squeeze casting, semi-solid forming, 6 lost foam casting 7 and vacuum die casting, 8 etc. Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 739 UDK 620.1:66.017:669.715 ISSN 1580-2949 Original scientific article/Izvirni znanstveni ~lanek MTAEC9, 53(5)739(2019) *Corresponding author's e-mail: hetao@sues.edu.cn The directional solidification (DS) technique used in this work is a new casting process that controls the unidi- rectional heat flow through specific temperature gradi- ents to achieve the desired orientation of the tissue and high-performance materials. 9 Especially in the study of changing the performance of aluminum-based alloys, 10,11 it has been rapidly developed since its birth. Y. J. Sun et al. 12 studied the effect of directional solidification on the microstructure and properties of pure aluminum; the re- sults show that the directional solidification can improve the electrical resistivity of the aluminum rods compared with the ordinary casting process. G. Wan et al. 13 studied the effects of current treatment on the DS of the Al-Si al- loy, the results show that the directional solidification is the most obvious at the pulling rates of 3 mm/min. K. Q. Sun et al. 14 studied the effect of melt overheating on the microstructure and properties of the DS of the Al-Cu al- loy. The results show that the strength of the alloy in- creases by nearly 60 % and the elongation nearly dou- bled after the melt overheat treatment. L. H. Cui et al. 15 studied the effects of Cu content on the DS of Al-Cu al- loy; it was found that when the content of Cu increased from 1.77 % to 3.00 %, the spacing of primary dendrite increased gradually, but the increase of dendrite spacing was small. N. C. Si et al. 16 studied the effects of the tem- perature gradient on the primary dendrite spacing of the directionally solidified Al-4.5 % Cu alloy. The results show that when the other solidification parameters are unchanged, with the increase of temperature gradient, the primary dendrites become smaller and smaller, straight, basically parallel distribution. It can be seen that the research on the DS of Al-base alloys is mainly fo- cused on the study of alloy properties by changing the chemical composition of the alloy, the processing method and changing a single processing parameter. However, few researches focus on the comprehensive ef- fect of multiple processing parameters on the micro- structure and properties of the DS Al-based alloys. Fur- thermore, the electrical resistivity of Al-based alloys has no related studies. Therefore, the aim of this work was to investigate the effects of three processing parameters, i.e., the melting temperatures, the pulling rates and the vacuum, on the microstructure, mechanical properties and electrical re- sistivity of the Al-Si-Cu alloy under DS conditions. Based on the above objectives, we have done the follow- ing work: firstly, Al-Si-Cu alloy rods are prepared using DS under different process parameters. Secondly, a scan- ning electron microscope (SEM), JVJ–50s test machine, MHVD–1000IS microhardness tester and FT300 resis- tivity tester are used to measure the microstructure, me- chanical properties and electrical resistivity. Finally, the correlation between the processing parameters and the microstructure and the properties are discussed to deter- mine the optimum range of processing parameters. 2 MATERIALS AND METHODS 2.1 Specimens prepared by directional solidification The DS experiment was carried out in high-vacuum DS equipment, as shown in Figure 1a. The schematic di- agram of the directional solidification system is shown in Figure 1b. DS equipment mainly consists of two parts: the electric arc melting function and the directional so- lidification function. The raw materials chemical compo- sition consists of 99.99 % Al, 99.95 % Si and 99.99 % Cu, etc., shown in Table 1. The raw material particles polished surface clean, put acetone in the surface with ultrasonic shocks out of the stain. Arc melting was car- ried out to ensure that the alloy was fully melted and mixed evenly. During the smelting process, electromag- netic stirring was applied and reversed repeatedly for more than five times to obtain the experimental speci- X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... 740 Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 Figure 1: a) directional solidification equipment, b) schematic diagram of directional solidification system 18 mens. Wire cutting equipment was used to take out the rod with a diameter of 10 mm × 150 mm as the DS spec- imen. The DS experiment was carried out using three stages: the heating stage, the insulation stage and the pulling stage. 1) The heating stage: the alloy test rods were placed in a crucible with an inner diameter of 10 mm in the DS equipment. The crucible was an Al 2 O 3 co- rundum tube with a purity of 99.9 %. 2) The furnace of the DS equipment was pumped to a high vaccum using a mechanical pump and a molecular pump. 3) The heating furnace was filled with high-purity argon gas. The alloy rod was heated and melted by resistance heating in a non-pollution environment. To prevent the consumption of alloy elements from evaporation, when the tempera- ture of the test rod reaches the set temperature by the thermocouple, stop heating and begin to enter the insula- tion stage, which lasts for 5 min. 4) The smelten alloy rod was pulled into the Ga-In alloy solution with a cer- tain pulling rate, when the alloy was cooled to ordinary temperature, the DS experiment was completed. The DS specimens were obtained, as shown in Figure 2.5)The DS specimens were heat treated in a SX2-5-12N box re- sistance furnace following the T6 temper, which com- prised solution heat treatment at 540 °C for 8 h, followed by quenching in 60 °C water. The specimens were then aged at room temperature for 24 h, followed by artificial aging at 155 °C for 5 h, then air cooled. 17 Table 1: Al-Si-Cu alloy chemical composition (w/%) Al Si Cu Fe Mn Zn 87.7 7 4 0.5 0.5 0.3 In DS experiment, different DS specimens were pre- pared by changing the processing parameters. The melt- ing temperatures varied from 700 °C to 800 °C. The pulling rates varied from 50 μm·s –1 to 300 μm·s –1 , and the vacuum degree of smelting changes in the range of 4×10 –4 MPato1.2×10 –3 MPa, shown in Table 2. 2.2 Mechanical properties test of specimens Figure 3 shows the standard plate-shaped tension specimen. Tensile tests were conducted following the ASTM: E8M standard. The mechanical properties were measured using the JVJ–50s tension machine at room temperature. The tension speed of the specimens was 1 mm·min –1 . The microhardness of the transverse section was measured by the MHVD-1000IS microhardness tester. Specimens were polished with the abrasive paper of #800 to #2000, cleaned and blown dry with a hair dryer, then placed on a microhardness tester with a set load of 200 N, maintaining the load for 3 s. The microhardness of 7 points was measured, a point was measured 10 times and the average value being obtained. 2.3 Electrical properties test of specimens The specimen with a size of 10 mm × 15 mm was cut by the DK7632-type linear cutting machine. The surface of the specimen was polished by using water and alcohol to ensure that the surface was smooth and bright. The re- sistivity of the specimens was tested by using the four-terminal measuring method with an FT300 resistiv- ity tester. X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 741 Figure 3: Tension specimens Figure 2: Directional solidification specimens Table 2: Processing parameters of directionally solidified Al-Si-Cu al- loy Experiment number Smelting tem- perature (°C) Pulling rates (μm·s –1 ) Vacuum (× 10 –3 MPa) 1 700 50 0.8 2 700 100 0.8 3 700 200 0.8 4 700 300 0.8 5 750 50 0.4 6 750 50 0.8 7 750 50 1.2 8 750 100 0.8 9 750 200 0.8 10 750 300 0.8 11 800 50 0.8 12 800 100 0.8 13 800 200 0.8 14 800 300 0.8 2.4 Microstructure observation of specimens Observation specimens were prepared with a size of 2mm×2mm×2mmusing a linear cutting machine. Grinding and polishing were performed using the ma- chine. Specimens were etched within a solution of 0.5 % HF with 10 s, and then were washed with water and alco- hol. Finally, blown dry with a blower. The microstruc- tures of the specimens were captured by SEM. 3 RESULTS AND DISCUSSION 3.1 Microstructure analysis Figure 4 shows the microstructure of the Al-Si-Cu alloy at different melting temperatures of (700, 750 and 800) °C under the pulling rates of 100 μm·s –1 at vacuum degree of8×10 –4 MPa. It can be seen from Figure 4a that the solid-solution dendrites are coarse at 700 °C, which are irregularly distributed in the -Al matrix. And, there are many eutectics and some disk-shaped eutectic compounds in Figure 4a. The grain boundaries can be clearly seen from Figure 4b, and a large number of fine second-phase granular eutectics and strengthening phases are dispersed and precipitated in the vicinity of grain boundaries. The solid-solution dendrites are further refined compared with Figure 4a. At the same time, a small amount of disk eutectic compounds was distrib- uted. It can be seen from Figure 4c that the melting grain boundary disappeared. A large number of short rod-shaped eutectics were found around the matrix, X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... 742 Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 Figure 5: Microstructure of Al-Si-Cu alloy at different degree of vac- uum with: a) 1.2 × 10 –3 MPa,b)8×10 –4 MPaandc)4×10 –4 MPa Figure 4: Microstructure of Al-Si-Cu alloy at different melting tem- peratures with: a) 700 °C, b) 750 °C and c) 800 °C which are unevenly distributed and also produced a small amount of strip-shaped and plate-shaped eutectics. Figure 5 shows the effect of the vacuum degree on the microstructure of the Al-Si-Cu alloy under a certain melting temperature of 750 °C and pulling rate of 50 μm·s –1 . It can be seen from Figure 5a that there are more defects, shrinkage and pinus more defects when the vac- u u md e g r e ei s8×1 0 –4 MPa, the defects of alloy microstructure are obviously reduced, shown in Figure 5b.The size and number of shrinkage pinus are obviously reduced, and a few areas of micro porosity are produced. Figure 5c shows that, the alloy evenly organized and the densification effect of the alloy is remarkable, and no ob- vious defects of the microstructure are produced when the vacuum degree is4×10 –4 MPa. 3.2 Effect of the melting temperatures and pulling rates on the mechanical properties and electrical properties of Al-Si-Cu alloy Figure 6 shows the effect of the melting temperatures and pulling rates on mechanical properties and electrical properties of Al-Si-Cu alloy. It can be seen from Figure 6a that the tension strength of the directional solidifica- tion alloy first increases and then decreases with the in- crease of the melting temperatures. When the melting temperature was 750 °C, the maximum tension strength was 232 MPa. Compared to sand mould casting Al-Si-Cu alloy, 19 the tension strength increased by about 18.97 %. In general, at 750 °C, the tension strength of the Al-Si-Cu alloys was the highest. Additionally, the tension strength of Al-Si-Cu alloy first decreases and then increases with the increase of the pulling rates at a given melting temperature. When the pulling rates in- crease from 100 μm·s –1 to 300 μm·s –1 , the tension strength of the alloy increased about 23.6 %. So, the pulling rates have a significant influence on the tension strength. It can be seen from Figure 6b that the elonga- tion at break increases with the increase of the pulling rates. When the pulling rate increases from 50 μm·s –1 to 300 μm·s –1 at a given melting temperature, the elongation at break of the Al-Si-Cu alloy increased about 33–50 %. With the increase of melting temperatures, the elongation at break of the alloy increased first and then decreased. Figure 6c shows the effect of different processing pa- rameters on the microhardness of the Al-Si-Cu alloy, when the pulling rates increases from 50 μm·s –1 to 300 μm·s –1 at a given melting temperature, the microhardness of the specimen increases. When the melting temperature was 750 °C and the pulling rate was 300 μm·s –1 , the max- imum microhardness of the alloy was 102 HV. X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 743 Figure 6: The effect of the melting temperatures and pulling rates on the mechanical properties and electrical properties of the Al-Si-Cu alloy Mechanical properties variation trend depends on the microstructure evolution in Figure 4.InFigure 4a, the dendrite of solid solution on -Al matrix is coarse and uneven. A coarse dendrite structure easily leads to stress concentration, which produces microcracks, and will ac- celerate the crack growth. Thus, the strength and micro- hardness of the alloy were reduced. In Figure 4b, with the improvement of melting temperatures, the dendritic structure is refined, similar to A356 alloy proposed by H. Liao. 20 Dispersion strengthened granular eutectic not only increases the strength and plasticity of the alloy but also enhances the toughness of the Al-Si-Cu alloy. So, the mechanical properties of the alloy are better. In Fig- ure 4c, when the melting temperature continues to rise, the results in granular eutectic aggregation, coarsening phenomenon, so reduces the strength and plasticity of the alloy. Figure 6d shows the effects of melting temperatures and pulling rates on the electrical resistivity of the Al-Si-Cu alloy. At room temperature, pure aluminium had a resistivity of 2.94 × 10 2 μ ·mm and the pure sili- con a resistivity of 2.52 × 10 5 μ ·mm. The resistivity of pure copper was 1.85 × 10 2 μ ·mm. 21 As can be seen from Figure 6d, the resistivity of the novel Al-Si-Cu al- loy was lower than that of any alloying element. When the pulling rate varies from 50 μm·s –1 to 200 μm·s –1 , the resistivity gradually decreases. When the pulling rate ex- ceeds 200 μm·s –1 , the resistivity sharply increases, the re- sistivity increased about 41.9 %. When the melting tem- perature was 750 °C and the pulling rate was 200 μm·s –1 , the average resistivity was about 18.7 μ ·mm. It indi- cates that the conductivity was better at the melting tem- peratures of 750 °C and the pulling rate of 200 μm·s –1 . As shown in Figure 4, when the melting temperature was 700 °C, the solid solution on the -Al matrix has coarse dendrites, and there are many eutectics in the form of strip and plate and some discoid eutectic com- pounds. Most of these eutectic structures composed of silicon. 22 Silicon is a semiconductor material, which has less conductivity than metal compounds at room temper- ature. Many primary silicon and eutectic silicon are dis- ordered along with the growth direction, which against current delivery, so the resistivity is larger. When the melting temperature was 750 °C, a large number of fine secondary granular eutectic and strengthening phases are dispersed in the -Al matrix, and the dendrite structure of the solid solution is further evenly refined, as shown in Figure 4b. The fine microstructure is beneficial to current delivery, so the resistivity is less. As the tempera- ture of 800 °C, too high temperature results in a large number of second phase short rod eutectic and a small amount of stripe and lamellar eutectic in the -Al matrix, as shown in Figure 4c. It also increases the current hin- drance, which leads to an increase of the resistivity. 3.3 Effects of vacuum degrees on the mechanical prop- erties and electrical resistivity of Al-Si-Cu alloy Figure 7 shows the effects of different vacuum de- grees on the mechanical properties and electrical resistiv- ity of Al-Si-Cu alloy. It can be seen from Figure 7a that the tension strength decreases with the increase of the degree of vacuum. When vacuum degree was 1.2 × 10 –3 MPa, the tension strength of the alloy was the lowest, i.e., 191 MPa. When the vacuum degree was 0.4 × 10 –3 MPa, the tension strength of the alloy reaches 226 MPa, which is about 19 % higher than that of the alloy rod at the vacuum degree of 1.2 × 10 –3 MPa. Figure 7a shows that the elongation at break of the alloy rod first in- creases and then decreases with the increase of the de- gree of vacuum, and the maximum elongation at break X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... 744 Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 Figure 7: Effects of different vacuum degrees on the mechanical prop- erties and electrical resistivity of the Al-Si-Cu alloy was43%.Figure 7b shows that when the degree of vac- uum increased from 0.8 × 10 –3 MPato1.2×10 –3 MPa, the microhardness of the alloy decreased rarely. As the vacuum continues to decrease, the microhardness of the alloy rod increases rapidly, and the microhardness reaches 102 HV at 0.4 × 10 –3 MPa. Compared with 1.2 × 10 –3 MPa, the microhardness of the alloy rod increases by about 30.7 %. C. Lee et al. 23 found that the tension properties of Al–Si alloys depend on the microstructural characteris- tics. It can be seen from Figure 5 that the microstructure of the alloy rod was compact at 0.4 × 10 –3 MPa, and no cracks, shrinkage porosity and other defects were ob- served. With the decrease of vacuum degree, the shrink- age pinus, micro porosity, crack and other defects in the test rods were obviously decreased and accompanied by inclusions. The shrinkage pinus is caused by liquid shrinkage and volume shrinkage between solid and liq- uid lines during solidification of the alloy. The vacuum degree is too low, the original air in the cavity invades the liquid metal. Figure 7c shows the effect of different vacuum de- grees on the electrical resistivity of the Al-Si-Cu alloy. It can be seen that the resistivity of the test rods gradually decreases with the increases of the degree of vacuum, and the conductive ability becomes better. When the de- gree of vacuum was 0.4 × 10 –3 MPa, the lowest resistiv- ity was 17.6 μ ·mm. It can be seen from Figure 5 that when the vacuum degree is lower, the microstructure de- fects are much more, so that the resistivity of the alloy is higher. 4 CONCLUSIONS 1) With the increase of melting temperatures, the eutectic on the -Al matrix was refined from strip and plate to short rod and granular, and the number of second phases increased. When the melting temperature is too high, the second phase begins to coarsen and grow. At 750 °C, the microstructure of Al-Si-Cu is the best and more uniform. Furthermore, the higher the vacuum de- gree of the alloy in solidification process, the less defects within the microstructure of the alloy. 2) With the increase of the pulling rates, the tension strength first decreases and then increases, the elongation at break and microhardness increase all the time, the re- sistivity first decreases and then increases. At the melting temperature of 750 °C and the pulling rate of 300 μm·s –1 , the mechanical properties of the alloy are the best, i.e., the tension strength is 232 MPa, and the microhardness is 102 HV, the maximum tension strength and micro- hardness increased about 21.4 % and 47.1 %, respec- tively. At the melting temperature of 750 °C and the pull- ing rate of 200 μm·s –1 , the electrical properties of the Al-Si-Cu are the best, the minimum resistivity is 18.2 μ ·mm. 3) With the increase of the vacuum degrees, the ten- sion strength and microhardness of the alloy gradually increase, and the electrical resistivity gradually de- creases. The maximum tension strength and microhard- ness of the Al-Si-Cu alloy is 226 MPa and 102 HV, re- spectively, at a vacuum degree of 0.4 × 10 –3 MPa. When the vacuum degree is 0.4 × 10 –3 MPa, the minimum elec- trical resistivity is the best, i.e., 17.6 μW·mm. Acknowledgements This project is funded by National Key Research and Development Program of China (Grant no. 2018YFB1307900), Key Research Program of Shanghai Science and Technology Commission (Grant no. 16030501200), National Natural Science Foundation of China (Grant No. 51805314) and Shanghai University of Engineering and Science (Grant No. E3-0903-17-01006 & no. E3-0501-18-01002). The Robot Functional Ma- terials Preparation Laboratory in Shanghai University of Engineering Science is also gratefully acknowledged. 5 REFERENCES 1 P. Ebrahimzad, M. Ghasempar, M. Balali, Friction stir processing of aerospace aluminum alloy by addition of carbon nano tube, Transactions of the Indian Institute of Metals, 70 (2017) 1–13, doi:10.1007/s12666-017-1062-5 2 H. Kaya, A. Aker, Effect of alloying elements and growth rates on microstructure and mechanical properties in the directionally solidified Al–Si–X alloys, Journal of Alloys & Compounds, 694 (2017) 145–154, doi:10.1016/j.jallcom.2016.09.199 3 S. K. Rathi, A. Sharma, M. D. Sabatino, Performance of Al–5Ti–1B master alloy after ball milling on minimizing hot tearing in Al–7Si–3Cu alloy, Transactions of the Indian Institute of Metals, 70 (2017) 827–831, doi:10.4028/www.scientific.net/KEM.737.27 4 K. S. Alhawari, K. S. Omar, M. J. Ghazali, Microstructure evolution of semi-solid Al–Si–Cu alloys with different Mg contents, Chinese Journal of Nonferrous Metals, 27 (2017), doi:10.1016/S1003- 6326(17)60169-9 5 V. Maja, M. Jozef, B. Tonica, Z. Franc, Effect of Ce on (Al) -Al2Cu eutectic morphology in Al-Si-Cu alloys, Chinese Journal of Nonferrous Metals, 1 (2014) 36–41, doi:10.1016/S1003- 6326(14)63025-9 6 A. Kolahdooz, S. A. Dehkordi, Effects of important parameters in the production of Al-A356 alloy by semi-solid forming process, Journal of Materials Research & Technology, (2018), doi:10.1016/j.jmrt. 2017.11.005 7 J. Hassan, M. H. Idris, A. Shayganpour, Significant processing parameters affecting the quality of Al-Si-Cu alloy thin-wall castings during EPC, Chinese Journal of Nonferrous Metals, 10 (2013) 2843–2851, doi:10.1016/S1003-6326(13)62805-8 8 C. Y. Jin, S. X. Zhang, T. Sun, X. C. Quan, Effect of vacuum die casting technology on the appearance quality and mechanical properties of aluminum alloy die castings, Foundry, (2016), doi:10.3969/j.issn.1001-4977.2016.06.007 9 Y. G. Wen, C. J. Cui, L. L. Tian, M. Yang, T. Xue, Progress and application of directional solidification technology, Materia News, 30 (2016) 116–120, doi:10.11896/j.issn.1005-023X.2016.03.022 10 R. P. Mooney, S. Mcfadden, M. Rebow, D. J. Browne, A front tracking model for transient solidification of Al–7wt%Si in a Bridgman furnace, Transactions of the Indian Institute of Metals, 65 (2012) 527–530, doi:10.1007/s12666-012-0201-2 X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746 745 11 A. Dennstedt, L. Ratke, Microstructures of directionally solidified Al–Ag–Cu ternary eutectics, Transactions of the Indian Institute of Metals, 65 (2012) 777–782, doi:10.1007/s12666-012-0172-3 12 Y. J. Sun, Q. Y. Li, X. Li, Y. J. Lin, Preparation of directional soli- dified pure aluminum test rod and its microstructure and properties, Journal of thermal processing, 42 (2013) 56–58, doi:10.14158/ j.cnki.1001-3814.2013.01.018 13 G. Wan, B. L. Wu, H. S. Wang, Y. H. Zhao, Effect of current treatment on directional solidification of Al–Si alloy, Casting, 53 (2004) 1001–1004, doi:10.3321/j.issn:1001-4977.2004.12.012 14 K. Q. Sun, Effect of melt overheating on the melt structure and directional solidification structure and properties of Al-Cu alloy, Jiangsu University, (2005), doi:10.7666/d.y827168 15 L. H. Cui, J. L. Pang, D. Y. Li, Effect of Cu content on directional solidification structure and primary dendritic spacing in Al–Cu alloys, Hot Processing Technology, 40 (2011) 34–37, doi:10.3969/ j.issn.1001-3814.2011.15.011 16 N. C. Si, N. J. Xu, S. H. Si, Y. D. Li, J. Shi, Effect of temperature gradient on primary dendritic spacing in directional solidification Al-4.5% Cu alloy, Materials and Engineering, (2011) 75–79, doi:10.3969/j.issn.1001-4381.2011.04.016 17 E. Samuel, B. Golbahar, A. M. Samuel, H. W. Doty, S. Valtierra, F. H. Samuel, Effect of grain refiner on the tensile and impact proper- ties of Al–Si–Mg cast alloys, Materials & Design, 56 (2014) 468–479, doi:10.1016/j.matdes.2013.11.058 18 T. He, L. Min, Y. M. Huo, H. J. Liu, X. J. Yi, Effect of temperatures and pulling rates on microstructure and mechanical properties of 6061 aluminum alloy in directional solidification, Mechanika, 24 (2018), doi:10.5755/j01.mech.24.1.19499 19 X. W. Hu, F. R. Ai, H. Yan, Influences of pouring temperature and cooling rate on microstructure and mechanical properties of casting Al-Si-Cu aluminum alloy, Acta Metallurgica Sinica, 82 (2012) 2105–2110, doi:10.11890/1006-7191-124-272 20 H. C. Liao, Y. Sun, G. X. Sun, Correlation between mechanical pro- perties and amount of dendritic -Al phase in as-cast near-eutectic Al–11.6% Si alloys modified with strontium, Materials Science & Engineering A, 335 (2002) 62–66, doi:10.1016/S0921-5093(01) 01949-9 21 H. M. Shi, H. Wang, H. Y. Li, J. Y. Lin, Formation mechanism and improvement of sidewall holes in Al–Cu interconnection wires, Chinese Journal of Semiconductors, 34 (2009) 569–572, doi:10.3969/j.issn.1003-353x.2009.06.014 22 Y. X. Jin, K. Ji, X. H. Fu, Al–P–Re–Sr composite metamorphic hypereutectic Al-Si alloy, Journal of Jiangsu University of Science and Technology, 37 (2008) 48–51, doi:10.3969/j.issn.1001- 3814.2008.11.010 X. YI et al.: MICROSTRUCTURE EVOLUTION AND PROPERTY CHANGES OF Al-Si-Cu ALLOY ... 746 Materiali in tehnologije / Materials and technology 53 (2019) 5, 739–746