Three-dimensional visualization and quantification of microporosity in aluminum castings by X-ray micro-computed tomography

doi:10.1016/j.jmst.2020.03.088

Abstract

Abstract:

Porosity is a major issue in solidification processing of metallic materials. In this work, wedge die casting experiments were designed to investigate the effect of cooling rate on microporosity in an aluminum alloy A356. Microstructure information including dendrites and porosity were measured and observed by optical microscopy and X-ray micro-computed tomography (XMCT). The effects of cooling rate on secondary dendrite arm spacing (SDAS) and porosity were discussed. The relationship between SDAS and cooling rate was established and validated using a mathematical model. Three-dimensional (3-D) porosity information, including porosity percentage, pore volume, and pore number, was determined by XMCT. With the cooling rate decreasing from a lower to a higher position of the wedge die, the observed pore number decreases, the porosity percentage increases, and the equivalent pore radius increases. Sphericity of the pores was discussed as an empirical criterion to distinguish the types of porosity. For different cooling rates, the larger the equivalent pore radius is, the lower the sphericity of the pores. This research suggests that XMCT is a useful tool to provide critical 3-D porosity information for integrated computational materials engineering (ICME) design and process optimization of solidification products.

Key words: X-ray computed tomography, Casting micropore, Quantitative evaluation, Al alloy

Cheng Gu, Yan Lu, Alan A. Luo. Three-dimensional visualization and quantification of microporosity in aluminum castings by X-ray micro-computed tomography[J]. J. Mater. Sci. Technol., 2021, 65: 99-107.

Figures/Tables 12

Table 1 Chemical composition (wt.%) of A356 alloy used in this study.

Si	Mg	Ti	Fe	Sr	V	Al
6.78	0.33	0.13	0.11	0.02	0.015	Bal.

Fig. 1. (a) Designed V-shaped wedge die, (b) actual wedge die, and (c) schematic of wedge casting, (d) wedge casting sample, and (e) cylinder specimen at each location.

Fig. 2. (a) HeliScan? microCT device used in this study, and (b) schematic of XMCT scan setup.

Fig. 3. Measured cooling curves of different cylinders.

Fig. 4. Optical microstructure with dendrite and porosity morphology of (a-c) Cylinder A, (d-f) Cylinder B, and (g-i) Cylinder C.

Fig. 5. (a) Secondary dendrite arm spacing as a function of cooling rate: comparison between experiment and model prediction; (b) Schematic of secondary dendrite arm spacing and the solute layer.

Fig. 6. XMCT scanning of different cylinders: (a-c) longitudinal section, and (d-f) horizontal section; (a, d) Cylinder A, (b, e) Cylinder B, and (c, f) Cylinder C.

Fig. 7. 3-D XMCT results: (a-c) cylinder structure including solid and gas, and (d-f) gas morphology and distribution in the cylinder; (a, d) Cylinder A, (b, e) Cylinder B, and (c, f) Cylinder C (Solid phase is in green color, and gas phase is in black color).

Fig. 8. Porosity percentage and pore number with the relationship to cooling rate, respectively.

Fig. 9. Relationship between equivalent pore radius and cooling rate.

Fig. 10. XMCT results in 1 mm × 1 mm × 1 mm cubic captured from different cylinders: (a1-a3) Cylinder A, (b1-b3) Cylinder B, and (c1-c3) Cylinder C.

Fig. 11. Relationship between sphericity and equivalent pore radius.

References 29

[1]	J. Xu, Y. Rong, Y. Huang, P. Wang, C. Wang, J. Mater. Process. Technol. 252 (2018) 720-727. DOI URL
[2]	Q. Dong, J. Zhang, B. Wang, X. Zhao, J. Mater. Process. Technol. 238 (2016) 81-88. DOI URL
[3]	H.R. Ammar, A.M. Samuel, F.H. Samuel, Mater. Sci. Eng. A 473 (2008) 65-75. DOI URL
[4]	C. Zhang, M. Gao, D. Wang, J. Yin, X. Zeng, J. Mater. Process. Technol. 240 (2017) 217-222. DOI URL
[5]	J.P. Anson, J.E. Gruzleski, Mater. Charact. 43 (1999) 319-335. DOI URL
[6]	W. Ren, Z. Yang, R. Sharma, C. Zhang, P.J. Withers, Eng. Fract. Mech. 133 (2015) 24-39.
[7]	S.R. Stock, Int. Mater. Rev. 53 (2008) 129-181. DOI URL
[8]	D. Pires, J.L. Hedrick, A. De Silva, J. Frommer, B. Gotsmann, H. Wolf, M. Despont, U. Duerig, A.W. Knoll, Science 328 (2010) 732-736. DOI URL PMID
[9]	E. Maire, P.J. Withers, Inter. Mater. Rev. 59 (2014) 1-43. DOI URL
[10]	S. Maleksaeedi, H. Eng, F.E. Wiria, T.M.H. Ha, Z. He, J. Mater. Process. Technol. 214 (2014) 1301-1306. DOI URL
[11]	Y. Huang, Z. Yang, W. Ren, G. Liu, C. Zhang, Int. J. Solids Struct. 67-68 (2015) 340-352. DOI URL
[12]	Y. Huang, D. Yan, Z. Yang, G. Liu, Eng. Fract. Mech. 163 (2016) 37-54. DOI URL
[13]	A. Fritzsche, K. Hilgenberg, F. Teichmann, H. Pries, K. Dilger, M. Rethmeier, J. Mater. Process. Technol. 253 (2018) 51-56. DOI URL
[14]	G. Chen, Q. Zhou, S.Y. Zhao, J.O. Yin, P. Tan, Z.F. Li, Y. Ge, J. Wang, H.P. Tang, Powder Technol. 330 (2018) 425-430. DOI URL
[15]	N. Limodin, A. El Bartali, L. Wang, J. Lachambre, J.Y. Buffiere, E. Charkaluk, Nucl. Instruments Methods Phys. Res. Sect. B Beam Interact. with Mater. Atoms 324 (2014) 57-62.
[16]	J.Y. Buffière, E. Maire, J. Adrien, J.P. Masse, E. Boller, Exp. Mech. 50 (2010) 289-305. DOI URL
[17]	S.C. Wu, C. Yu, P.S. Yu, J.Y. Buffière, L. Helfen, Y.N. Fu, Mater. Sci. Eng. A 651 (2016) 604-614. DOI URL
[18]	S.C. Wu, T.Q. Xiao, P.J. Withers, Eng. Frac. Mech. 182 (2017) 127-156. DOI URL
[19]	H. Toda, S. Masuda, R. Batres, M. Kobayashi, S. Aoyama, M. Onodera, R. Furusawa, K. Uesugi, A. Takeuchi, Y. Suzuki, Acta Mater. 59 (2011) 4990-4998. DOI URL
[20]	A.A. Luo, Calphad Comput. Coupling Phase Diagrams Thermochem. 50 (2015) 6-22. DOI URL
[21]	J.H. Jeon, D.H. Bae, J. Alloys. Compd. 808 (2019), 151756. DOI URL
[22]	R.N. Grugel, J. Mater. Sci. 28 (1993) 677-683. DOI URL
[23]	Z. Li, Y. Jing, H. Guo, X. Sun, K. Yu, A. Yu, X. Jiang, X.J. Yang, Metall. Mater. Trans. B Process Metall.Mater. Process. Sci. 50 (2019) 1204-1212.
[24]	P. Yousefian, M. Tiryakioğlu, Metall. Mater. Trans. A 49 (2018) 563-575. DOI URL
[25]	E. Plancher, P. Gravier, E. Chauvet, J. Blandin, E. Boller, G. Martin, L. Salvo, P. Lhuissier, Acta Mater. 181 (2019) 1-9. DOI URL
[26]	M. Pham, B. Dovgyy, P.A. Hooper, C.M. Gourlay, A. Piglione, Nat. Commun. 11 (2020) 749. DOI URL PMID
[27]	G.K. Sigworth, C. Wang, Metall. Trans. B 24 (1993) 349-364. DOI URL
[28]	C. Gu, Y. Lu, C.D. Ridgeway, E. Cinkilic, A.A. Luo, Sci. Rep. 9 (2019) 1-12. DOI URL PMID
[29]	J.P. Weiler, J.T. Wood, R.J. Klassen, E. Maire, R. Berkmortel, G. Wang, Mater. Sci. Eng. A 395 (2005) 315-322.107 DOI URL