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Ch. Fiał, E. Dudrova, M. Kabatova, M. Kupkova, M. Selecka, M. Sułowski and A. Ciaś

. Baran, A.H. Graham, A.B. Davala, R.J. Causton, C. Shade, A Superior Sinter-Hardenable Material, Advances in Powder Metallurgy and Particulate Materials 2 , 7, 185 (1999). [5] L. Girardini, A. Molinari, G. Locatelli, G. Tonini, Vacuum heat treatment of components for automotive applications, Metallurgia Italiana 2 , 26 (2006). [6] A. Ciaś, Effect of local sintering microatmosphere on mechanical properties of Fe-3Cr-0.5Mo-0.6C steel, Powder Metallurgy 56 , 3, 231 (2013). [7] A. Ciaś, A novel method of sintering hybrid steels in an improved

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D. Bochenek and P. Niemiec

. P łonska, Microchim. Acta 144, 9-15 (2004). [8] C. Kruea-In, S. Eitssayeam, K. Pengpat, G. Rujijanagul, Mater. Res. Bull. 47, 2859-2862 (2012). [9] J.A. Bartkowska, J. Ilczuk, Int. J. Thermophys. 31, 1-7 (2010). [10] N.K. Singh, P. Kumar, R. Rai, J. Alloys Compd. 509, 2957-2963 (2011). [11] K. Cwikiel, E. Nogas-Cwikiel, Phase Transit. 80, 1-2, 141-146 (2007). [12] D. Bochenek, Z. Surowiak, J. Poltierova -Vejpravova, J. Alloys Compds. 487, 572-576 (2009). [13] S. Saha, T

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R. Sathiskumar, N. Murugan, I. Dinaharan and S.J. Vijay

surface, Sci. Technol. Weld. Joining 14, 413-425 (2009). [8] P. Asadi, G. Faraji, M.K. Besharat i, Producing of AZ91/Si Ccomposite by friction stir processing (FSP), Int. J. Adv. Manuf. Technol. 51, 247-260 (2010). [9] M. Azizieh, A.H. Kokabi, P. Abachi, Effect of rotational speed and probe profile on microstructure and hardness of AZ31/Al 2 O 3 nanocomposites fabricated by friction stir processing, Mater. Des. 32, 247-260 (2011). [10] R. Salekrostam, M.K.B. Givi, P. Asadi, P. Ba - hemmat, Influence of Friction Stir

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K.W. Chung, C.-J. Kim and H.-S. Yoon

. Buchert, J. Clean. Prod. 51 , 1 (2013). [7] T.W. Ellis, F.A. Schmidt, L.L. Jones, Methods and opportunities in the recycling of rare earth based materials, in: K.C. Liddell, R.G. Bautista and R.J. Orth (Eds.), Metals and Materials Waste Reduction, Recovery and Remediation, The Minerals, Metals & Materials Soc., Pennsylvania 1994. [8] T. Saito, H. Sato, T. Motegi, J. Alloys. Comp. 425 , 145 (2006). [9] T. Itakura, R. Sasai, H. Itoh, J. Alloys. Comp. 408-412 , 1382 (2006). [10] J.-C. Lee, W.-B. Kim, J. Jeong, I.J. Yoon, J. Korean Inst. of Met

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B. Leszczynska-Madej

Attempts have been made to describe the influence of sintering temperature on the microstructure and properties of Al - SiC composites. Mixtures of 100%Al and Al - 5% SiC, Al - 10% SiC were produced by tumbling for 30 minutes in the Turbula T2F mixer. The powders were subsequently cold pressed at pressure 300MPa in a rigid die on a single action press. The green compacts were sintered in nitrogen at 580°C and 620°C for one hour. The main objective of this work was to determine influence of chemical composition and the manufacturing parameters on microstructure and properties of Al - SiC composites produced by powder metallurgy technology.

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T. Gancarz and J. Pstruś

REFERENCES [1] K. Suganuma, Curr. Opin. Solid. St. M. 5 , 55-64 (2001). [2] W.R. Osório, L.C. Peixoto, L.R. Garcia, N. Mangelinck-Noël, A. Garcia, J. Alloy Compd. 572 , 97-106 (2013). [3] M.F.M. Nazeri, A.A. Mohamad, J. Mater. Process. Tech. (2014), DOI: 10.1016/j.jmatprotec.2014.12.018 [4] M. Kitajima, T. Shono, Microelectron. Reliab. 45 , 1208-1214 (2005). [5] K. Berent, P. Fima, J. Pstrus, T. Gancarz, J. Mater. Eng. Perform. 23 , 1630-1633 (2014). [6] J-M. Song, P-C. Liu, C-L. Snih, K-L. Lin, J. Electron. Mater. 34

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K. Wojsyk, G. Golański, J. Jasak, J. Słania, A. Zieliński and P. Urbańczyk

REFERENCES [1] J. Brózda, Institute of Welding Bulletin 1 , 41 (2004). [2] A. Hernas, Energetyka cieplna i zawodowa 7, 18 (2004). [3] J. Brózda, M. Łomozik, M. Zeman, Institute of Welding Bulletin 5 , 23 (1997). [4] A. Iseda, M. Kubota, Y. Hayase, S. Yamammoto, K. Yoshikawa, The Sumitomo Search 36 , 17 (1988). [5] K. Haarmann, J. C. Vaillant, B. Vandenberghe, The T91/P91 book – Vallourec & Mannesmann Tubes – 2002, 2nd edition [6] J. Brózda, M. Zeman, Z. Cudek, Institute of Welding Bulletin 3 , 42 (2004). [7] J

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J. Pezda

REFERENCES [1] M. Panušková, E. Tillová, M. Chalupová, Strength of Materials 40 , 1, 98-101 (2008). [2] S. Kozhar, D. Regener, H. Zak, H. Altenbach, International Foundry Research/Giessereiforschung 62 , 2, 26-31 (2010). [3] F. Zupanič, T. Bončina, N. Rozman, B. Markoli, RMZ – Materials and Geoenvironment 58 , 1, 1-14 (2011). [4] J.C. Williams, E.A. Starke Jr., Acta Materialia 51 , 19, 5775-5779 (2003). [5] L.A. Dobrzański, Ł. Reimann, G. Krawczyk, Archives of Materials Science and Engineering 31 , 1, 37-40 (2008). [6] B

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A.H. Al-Azzawi, J. Sytchev and P. Baumli

REFERENCE [1] L. Segers, A. Fontana, R. Winand, Electrochimica Acta 36 (1), 41-47 (1991) [2] A. Bonomi, R. Habersaat, G Bienvenu, Surface Technology 6 (4), 313-319 (1978) [3] A. Girginov, T.Z. Tzvetkoff, M. Bojinov, Journal of Applied Electrochemistry 25 (11), 993-1003 (1995). [4] G. Kaptay, S.A. Kuznetsov, Plasmas & Ions 2 (2), 45-56 (1999). [5] H. Abe, K. Yoshii, K. Nishida, M. Imai, H. Kitazawa, Journal of Physics and Chemistry of Solids 66 (2-4), 406-409 (2005). [6] G. Kartal, S. Timur, C. Arslan, Journal of

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V. Vishnuh, S. Sudhakar, K. Tamilarasu, P. Prabhakaran and R. Rajasekar

method of gamma-beta durability determination for reliability tests of brand-new AC electromagnetic contactors, Int. T. Electr. Energy 10 (4), 219-224 (2000). [5] M.P. Paisios, C.G. Karagiannopoulos, P.D. Bourkas, Model for temperature estimation of dc-contactors with double-break main contacts, Simul. Model Pract. Th. 15 (5) 503-512 (2007). [6] L. Jiang, Z. Li, G. Fan, L. Cao, D. Zhang, The use of flake powder metallurgy to produce carbon nanotube (CNT)/aluminum composites with a homogenous CNT distribution, Carbon 50 (5), 1993