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B.P. Pisarek, D. Kołakowski and T. Pacyniak

Hot Tear Formation in a Magnesium Alloy Permanent Mold Casting. International Journal of Metalcasting. Fall 08, 41-53. [11] Norouzi, S., Shams, A., Farhangi, H. & Darvish, A. (2009). The temperature range in the simulation of residual stress and hot tearing during investment casting. International Scholarly and Scientific Research & Innovation. 3 (10), 558-564. [12] D’Elia, F., Ravindran, C., Sediako, D., Kainer, K.U. & Hort, N. (2014) Hot tearing mechanisms of B206 aluminum–copper alloy. Materials and Design. 64, 44-55. [13] Dong, S., Iwata

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E. Guzik and D. Wierzchowski

References [1] Gundlach, R. (1988). High-Alloy Graphitic Irons, Metals Handbook Ninth Edition. Casting . 15, 698-701. [2] Guzik, E. (2001). Some selected problems concerning the processes of cast iron improvement, Archives of Foundry Engineering. Monograph. No. 1M, 1-128. [3] Guzik, E., Asłanowicz, M., Kluk, R. (1995). Using cored wire in the production of nodular cast iron, Solidification of Metals and Alloys. 22, 76-81. [4] Guzik, E., Wierzchowski, D. (2012). Modern cored wire

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E. Guzik and D. Wierzchowski

References Guzik E. (2001). Some selected problems concerning the processes of cast iron improvement. Archives of Foundry Engineering. Polish Academy of Sciences - Katowice, Monograph, No. 1M, 1-128. Guzik E., Asłanowicz M., Kluk R. (1995). Using cored wire in the production of nodular cast iron. Solidification of Metals and Alloys. 22 , 76-81.

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E. Guzik, D. Kopyciński and D. Wierzchowski

References [1] R. Gundlach, High-Alloy Graphitic Irons, ASM Handbook. Casting 15, 1523-1526 (1998). [2] J. Yong-Xi, Material and technique of Si Mo heat-resistant vermicular iron exhaust manifold, China Foundry 3, 175-183 (2006). [3] D.L. Sponseller, Development of low-alloy ductile irons for service at 1200-1500 F, ASM Engineering Bookshelf. Source Book on Ductile Iron, 373-388 (1977). [4] E. Guzik, Some selected problems concerning the processes of cast iron improvement, Archives of Foundry

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T. Ciućka

References [1] Górny, Z. (1992). Casting alloys of non-ferrous metals. WNT, Warszawa (in Polish). [2] Mondolfo, L. F. (1976). Aluminium alloys. Structure and Properties. Butter Wooths, London, Boston. [3] Pietrowski, S. (1997). Piston silumins . Krzepnięcie metali i stopów , Vol. 29, PAN Katowice (in Polish). [4] Kojima, Y. (2000). Platform Science and Technology for Advanced Magnesium Alloys. Material Science Forum , 350-351 , Trans Tech Publications , Switzerland, 3

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A. Dziadoń, R. Mola and L. Błaż

References H. Friedrich, S. Schumann, Research for a "new age of magnesium" in the automotive industry. J. Mater. Process. Tech. 117 , 276-281 (2001). A. Bochenek, K.N. Braszczyńska, Structural analysis of the MgAl5 matrix cast composites containing SiC particles. Mat. Sci. Eng. A 290 , 122-127 (2000). R.A. Saravanan, M.K. Surappa, Fabrication and characterization of pure magnesium-30 vol.%SiC p particle composite. Mat. Sci. Eng. A 276 , 108-116 (2000

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J. Iwaszko and K. Kudła

R eferences [1] J. Iwaszko and M. Strzelecka, “Effect of cw-CO 2 laser surface treatment on structure and properties of AZ91 magnesium alloy”, Optics and Lasers in Engineering 81, 63–69 (2016). [2] P. Poza, C.J. Munez, M.A. Garrido, S. Vezzu, S. Rech, and A. Trentin, “Effect of laser remelting on the mechanical behaviour of Inconel 625 cold-sprayed coatings”, Procedia Engineering 10, 3799–3804 (2011). [3] I. Watanabe, M. McBridge, P. Newton, and K.S. Kurtz, “Laser surface treatment to improve mechanical properties of cast titanium”, Dental

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L.H. Cupido, P.L. Żak, N. Mahomed, J. Lelito, G. Piwowarski and P.K. Krajewski

International, 1826-2124 (1991). [22] E. Tillova, M. Chalupova, L. Hurtalova, Evolution of the Fe-rich phases in recycled AlSi9Cu3 cast alloy during solution treatment, Communications – Scientific Letters of University of Zilina 10 , 4, 95-101 (2010). [23] J. Lelito, P.L. Zak, A.L. Greer, J.S. Suchy, W.K. Krajewski, B. Gracz, M. Szucki, A.A. Shirzadi, Crystallization model of magnesium primary phase in the AZ91/SiC composite, Composites: Part B 43 , 3306-3309 (2012).

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G.C.M. Patel, P. Krishna, P.R. Vundavilli and M.B. Parappagoudar

Processing Technology. 186(1), 82-86. [23] Guo, Z.H., Hou, H., Zhao, Y.H. & Qu, S.W. (2012). Optimization of AZ80 magnesium alloy squeeze cast process parameters using morphological matrix. Transactions of Nonferrous Metals Society of China. 22(2), 411-418. [24] Bin, S.B., Xing, S.M., Zhao, N. & Li, L. (2013). Influence of technical parameters on strength and ductility of AlSi9Cu3 alloys in squeeze casting. Transactions of Nonferrous Metals Society of China. 23(4), 977-982. [25] Patel, G.C.M., Krishna, P. & Parappagoudar, M.B. (2015). Modelling of

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K. Łyczkowska, J. Adamiec, R. Jachym and K. Kwieciński

solidification process. Przegląd spawalnictwa. 1, 14-18. (in Polish). [5] Polshikhin, V., Prokhodovsky, A., Makhutin, M., Zoch, H. (2005). Integrated mechanical-metallurgical approach to modeling of solidification cracking in welds, In Bollinghaus T., Herold H. (Eds.) Hot cracking phenomena in welds, 223-244. Heidelberg - Germany: Springer. [6] Zupaniĉ, F., Bonĉina, T., Kiržman, A., Tichelaar, F.D. (2001). Structure of continuously cast Ni-based superalloy Inconel 713C. Journal of Alloys and Compounds. 329, 290-297. DOI 10.1016/S0925