Influence of pulse magneto-oscillation on the efficiency of grain refiner
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1 Adv. Manuf. (2017) 5: DOI /s Influence of pulse magneto-oscillation on the efficiency of grain refiner Tian-Yu Liu 1 Jie Sun 1 Cheng Sheng 1 Qi-Xin Wang 2 Yun-Hu Zhang 1 Li-Juan Li 1 Hong-Gang Zhong 1 Qi-Jie Zhai 1 Received: 2 November 2016 / Accepted: 21 April 2017 / Published online: 19 May 2017 Ó Shanghai University and Springer-Verlag Berlin Heidelberg 2017 Abstract Solidification experiments were carried out in Al-Cu (w(cu) = 5%) alloy to investigate the influence of pulse magneto-oscillation (PMO) on the efficiency of the Al3Ti1B refining agent at high superheat. The experimental solidification results show that the degree of superheat has remarkable influence on the efficiency of the grain refiner. However, the application of PMO has the potential to reduce the influence of superheat variation on the efficiency of the grain refiner. Finally, the mechanism underlying this phenomenon is discussed by performing a numerical simulation to show the forced flow inside the melt caused by PMO. Keywords Grain refinement Grain refiner Pulse magneto-oscillation (PMO) Al-Cu (w(cu) = 5%) alloy Solidification 1 Introduction Almost all metal alloys experience at least one solidification procedure during their production. The solidified structure of fine equiaxed grains can significantly enhance the mechanical properties of castings, ingots, and strips. Hence, grain refinement methods have been rigorously investigated and developed, such as the applications of a & Qi-Jie Zhai qjzhai@staff.shu.edu.cn 1 2 State Key Laboratory of Advanced Special Steels, Shanghai University, Shanghai , People s Republic of China College of Science, Shanghai University, Shanghai , People s Republic of China grain refiner [1 3], ultrasonic vibration [4 7], mechanical stirring [8 10], and electromagnetic fields [11 15]. In particular, grain refiners have been widely employed in the aluminum industry. Many kinds of grain refiners have been previously developed, including halide salts (K 2 TiF 6 and KBF 4 )[16, 17] and Al-Ti intermetallics (Al-B, Al-Ti-B, Al-Ti-B-Re, Al-Ti-B-C and Al-Ti-C) [18]. Among these, the Al-Ti-B grain refiner is more frequently used in the aluminum industry [19]. However, the degradation of grain refiners limits their applications, especially for the production of large aluminum casting or ingots. It was presented that the degradation caused the sedimentation and aggregation of grain refiner particles in the melt with a long holding time in Refs. [19 23]. Kearns et al. [21] proposed that the sedimentation of the Al-Ti-B grain refiner was due to TiAl 3 and TiB 2 particles having a higher density than the mother melt. Limmaneevichitr and Eidhed [22] confirmed this mechanism by performing related experiments and also found that the degradation of the grain refiner could be reduced by applying mechanical stirring in the melt. It has been recognized that the application of electromagnetic fields can influence the degradation of the grain refiner. For example, Chen et al. [23] investigated the effect of a rotating magnetic field on the degradation of the Al5Ti1B grain refiner in pure aluminum. It was found that a magnetic field intensity of 6 12 mt could significantly reduce sedimentation in the grain refiner due to the long holding time. However, the degradation of the grain refiner was enhanced when the intensity was increased to 18 mt because the aggregation of TiB 2 particles was triggered. Recently, Liang et al. [24, 25] presented that the application of pulsed magneto-oscillation (PMO) could generate a finer grain size in pure aluminum with the addition of the Al3Ti1B grain refiner.
2 144 T.-Y. Liu et al. In the present paper, the influence of PMO on the degradation of the grain refiner was investigated by performing solidification experiments under different superheat degrees. This is due to the fact that a higher superheat degree allows a longer sedimentation time and the increased possibility of aggregation of the grain refiner particle [20]. In addition, superheat is an important parameter in the production of alloys. Our investigation can provide a reference for the practical production of aluminum alloys with a grain refiner. 2 Experimental methods Al-Cu (w(cu) = 5%) alloy having liquidus temperature of 648 C was prepared by melting pure aluminum and pure copper. The prepared aluminum alloy samples with a weight of 550 g were located in a stainless steel crucible (U 70 mm 9 U 45 mm 9 80 mm, its thickness is 2 mm), and remelted in an electric resistance furnace to temperatures of 668 C, 688 C, and 708 C. After holding the temperature for 10 min, the Al3Ti1B intermediate alloy (Ti: 3.1%, B: 0.9%, Fe: 0.3%) with a commercial level of 10-3 Ti was added to the Al-Cu (w(cu) = 5%) melt through the free surface. Subsequently, mechanical stirring was performed to promote the dissolution of the grain refiner and homogenize the distribution of particles. Finally, the stainless steel crucible with the melt was placed within a PMO magnetic coil and treated with a parameter of 250h i A (current intensity), 2k i Hz (frequency), and 200f i ms (pulse length), where h i, k i and f i are constant coefficients of the power supply. The schematic view of the solidification experimental setup is shown in Fig. 1. To avoid the reaction between the Al-Cu (w(cu) = 5%) alloy and the steel crucible, the inner wall of the steel crucible was coated with boron nitride. Al3Ti1B was preheated to 300 C in another electric resistance furnace before addition into the Al-Cu (w(cu) = 5%) alloy melt. Fig. 1 Schematic diagram of experimental device Small units of 15 mm 9 15 mm 9 20 mm were sectioned from the center of the specimens, ground and polished from 6 lmto1lm. The prepared units were anodized by electrolytic polishing in u(hbf 4 = 4%) solution with a direct current of A/cm 2 for 20 s. The microstructures were photographed using a Zeiss microscope (Imager A2m) with polarized light. The average grain size was evaluated by the mean linear intercept method. 3 Results 3.1 Solidified structure Figure 2 shows the structures of the Al-Cu (w(cu) = 5%) alloy with the refining agent Al3Ti1B (10-3 Ti) solidified at the superheats of 20 C, 40 C, and 60 C. The solidified structures present significant grain refinement in the grain refiner treated Al-Cu (w(cu) = 5%) samples. In addition, it can be found that the transition from dendrite to sphere is remarkably promoted under the influence of the grain refiner regardless of the employed superheat. However, it is evident that the grain in the Al-Cu (w(cu) = 5%) sample becomes coarse with increasing degree of superheat. It indicates that the efficiency of the grain refiner is significantly influenced by the superheat. The Al-Cu (w(cu) = 5%) alloy treated by PMO was also solidified at different superheats of 20 C, 40 C, and 60 C. The corresponding solidified structures are shown in Fig. 3. In comparison with the structure of Al- Cu (w(cu) = 5%) alloy treated by grain refiner (see Fig. 2), the grain size is not reduced as much as the sample with grain refiner. The transition from dendrite to sphere in a sample influenced by PMO is also not so significant (see Fig. 3). The coarse dendritic morphology is even observed in samples with PMO. However, it is fortunate that grain size variation under different superheat degrees is not observed. It means that the grain size of sample driven by PMO is not sensitive to the varied superheat. Based on the achieved results, it is possible to improve the efficiency of the grain refiner at high superheat by applying PMO. Hence, the related solidification experiments of Al-Cu (w(cu) = 5%) alloy treated by both PMO and the grain refiner and solidified at different superheats were performed. As the corresponding solidified structure shown (see Fig. 4), when the PMO and the refining agent are applied together, the grains are much finer and more uniform than the samples only treated with the Al3Ti1B refining agent. It suggests that PMO can promote the efficiency of the grain refiner even at high superheat.
3 Influence of pulse magneto-oscillation on the efficiency of grain refiner 145 Fig. 2 Microstructures of Al-Cu (w(cu) = 5%) alloy with 10-3 Ti solidified at different preheated temperatures Fig. 3 Microstructures of Al-Cu (w(cu) = 5%) alloy solidified at different preheated temperatures under the treatment of PMO Fig. 4 Microstructures of Al-Cu (w(cu) = 5%) alloy treated by both PMO and grain refiner and solidified at different preheated temperatures 3.2 Grain size The measured grain size of the Al-Cu (w(cu) = 5%) alloy is shown in Table 1. It can be seen that the grain sizes of all samples solidified at different conditions gradually rise with increasing superheat. To characterize the trend of grain size coarsening with the increasing superheat degree, parameter K is defined as K ¼ S 3 S 1 ; ð1þ S S ¼ S 1 þ S 2 þ S 3 ; ð2þ 3 where S 1, S 2 and S 3 are the grain sizes corresponding to the samples cooled at the superheat of 20 C, 40 C and 60 C, respectively. Table 1 Measured grain sizes of Al-Cu (w(cu) = 5%) alloy at different experimental conditions Superheat degree/ C Grain size/lm Refining agent treatment PMO treatment PMO? Al3Ti1B treatment
4 146 T.-Y. Liu et al. The value of K reflects the variation amplitude of grain size controlled by the difference of superheat. As shown in Table 2, the grain refiner treated Al-Cu alloy with the highest value of K means that the grain size is significantly influenced by the variation of superheat. It indicates that the efficiency of the grain refiner is reduced at high superheat. A lower value of K is achieved when PMO was applied in the grain refiner treated sample (see Table 2). It suggests the efficiency of the grain refiner is improved by the application of PMO. The result obtained is consistent with the evolution of the solidified structure shown in Fig Numerical simulation 4.1 FEA simulation model To better understand the influence of PMO on the efficiency of the grain refiner, numerical simulation was performed to present the distribution of the electromagnetic force and flow field inside the melt. ANSYS finite element software was employed to develop the simulated domains and mesh (see Fig. 5). The electromagnetic parameters of the material are shown in Table 3. To simplify the mathematical model, the model was based on the following assumptions: (i) ignore the changes of melt density effected by temperature; (ii) the melt with a small amount of grain refiner particles is considered to be an incompressible Newtonian fluid; (iii) the current-carrying coil is a conductor with uniform current density; and (iv) since the geometry has axial symmetry, a two-dimensional model is employed. The induced magnetic field and electric current are calculated according to Maxwell s laws, which can be expressed as rh ¼ J þ od ot ; ð3þ re ¼ ob ot ; ð4þ Table 2 K values of Al-Cu (w(cu) = 5%) alloy at three different treatment conditions Treatment conditions K values Refining agent treatment 0.20 PMO treatment 0.06 PMO? Al3Ti1B treatment 0.11 Fig. 5 Schematic of numerical domain rb ¼ 0; rd ¼ q 0 ; ð5þ ð6þ where H is the magnetic field intensity vector, J the current density vector, D the electric flux density vector, E the electric field intensity vector, B the magnetic flux density vector, and q 0 the electric charge density. The electromagnetic force of the melt f can be expressed by the following formulae f ¼ JB; ð7þ J ¼ rðe þ vbþ; ð8þ B ¼ l 0 H; ð9þ where l 0 is the magnetic permeability, r the conductivity, and v the velocity vector. The numerical calculation of the flow field is based on the continuity equation and the momentum conservation equation, given by oq ot þ q ou i ¼ 0; ð10þ ox i q o u iu j ¼ op þ o l ou i þ o l ou j þ f ; ð11þ where q is the density of the melt, u i the velocity vector components in the radial direction and axial direction, P the external pressure, and l the effective coefficient of viscosity.
5 Influence of pulse magneto-oscillation on the efficiency of grain refiner 147 Table 3 Electrical parameter of materials Electrical resistivity/ (Xm) Relative permeability Al-Cu (w(cu) = 5%) (648 C) Coil Air (25 C) Simulated results Figure 6 presents the distribution of the electromagnetic force and flow field in the melt under the impact of PMO. As shown in Fig. 6a, the direction of the induced electromagnetic force is from the wall to the core of the melt. In addition, the strongest electromagnetic force is at the center of the coil. As a result, a stable vortex is generated inside the melt, as shown in Fig. 6b. In the upper part of the ingot, a counterclockwise flow circle is formed whereas a clockwise flow circle is observed in the lower part. This indicates that the applied PMO can cause global forced flow throughout the bulk melt. When PMO is combined with Al3Ti1B refining agent treatment, the forced flow inside the melt of Al-Cu (w(cu) = 5%) alloy has the ability to stir the grain refiner particles in the melt and result in homogeneous distribution. 5 Discussion The element Ti in the Al3Ti1B refinement agent has two states. 2.2%Ti appears in the form of TiB 2 as the heterogeneous substrate of the melt. The remaining 0.8%Ti appears in the form of solute [26], which promotes the formation of a constitutional undercooling region to cause nucleation. In addition, the solute Ti in the refining agent easily forms intermetallic TiAl 3 with Al in the melt as another nucleation site. However, the TiAl 3 formed is unstable and has a strong potential to aggregate [27], especially in melts with high superheat. Hence, when high superheat is employed, more TiAl 3 particles aggregated inside the melts. In addition, the higher superheat allows the TiB 2 particles exposed in the melt for a longer time to sedimentate. Eventually, the number of effective nucleation particles is significantly reduced. This is the reason that the efficiency of the grain refiner is significantly influenced by superheat, as presented in Sect. 3. It has been shown in the experimental results that PMO can reduce the influence of superheat on the efficiency of the grain refiner. This is because PMO induces forced convection in the melt. According to the numerically simulated results, since PMO has a high discharge frequency and narrow pulse width; the generated strong electromagnetic force causes a strong and global forced convection inside the melt. The flow intensity is much greater than that of the melt in natural convection. The forced flow generated can significantly reduce grain refiner particle aggregation and sedimentation, as well as suppress the decay of refiner in the melt with high superheat. This means that the application of PMO can promote the pour temperature of a melt with grain refiner to ensure the grain refinement and the fluidity of the melt. 6 Conclusions Fig. 6 a Melt electromagnetic force distribution with PMO treatment and b flow field in melt with PMO treatment This paper investigated the effects of PMO on the efficiency of the Al3Ti1B refining agent at different superheat temperatures. Results show that the solidified structures present significant grain refinement in the grain refinertreated Al-Cu (w(cu) = 5%) samples, but the efficiency of the grain refiner is significantly influenced by superheat. However, the grain size of samples treated by PMO is not sensitive to the degree of superheat. When the PMO and the refining agent are applied together, the finer grains generated with little variation in grain size at different superheat temperatures suggest that the application of PMO can significantly improve the efficiency of the refiner and delay refiner recession at high superheat. The simulated result shows that the forced flow generated by PMO
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