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Warianty tytułu
Języki publikacji
Abstrakty
Today’s industry aims at such situation, where number of defective products, so called defects shall approach to zero. Therefore, one introduces a various changes in technology of production, introduces improvements which would help in accomplishment of this objective. Another important factor is introduction of different type of testing, which shall help in assessment which factor has significant effect on quantity of rejects, and which one could be neglected. Existence of casting rejects is unavoidable; therefore a new ideas, technologies and innovations are necessary in the entire widely understood foundry branch, in order to minimize such adverse effect. Performance of tests aimed at unequivocal determination of an effect of vibrations during crystallization on mechanical properties and porosity of the EN AC-AlSi17 alloy was the objective of the present work. To do this, there were produced 36 castings from EN AC-AlSi17 alloy. All the castings underwent machining operations. Half of the casting was destined to strength tests, the other half served to determination of an effect of vibrations on porosity of the alloy. The specimens were divided into 12 groups, depending on amplitude of vibrations and tilt angle of metal mould during pouring operation.
Czasopismo
Rocznik
Tom
Strony
5--8
Opis fizyczny
Bibliogr. 15 poz., rys., tab., wykr.
Twórcy
autor
- Department of Technology of Machinery and Automation, Faculty of Chipless Forming Technology, University of Bielsko-Biała, Willowa 2, 43- 300 Bielsko-Biała, Poland
Bibliografia
- [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. PAN Krzepnięcie metali i stopów, Zeszyt 29, Monografia, Katowice (in Polish).
- [4] Kojima. Y. (2000). Platform Science and Technology for Advanced Magnesium Alloys. Material Science Forum, vol. 350-351, Trans Tech Publications, Switzerland, pp. 3-18.
- [5] Pietrowski, S. (2001). Silumins. Wydawnictwo Politechniki Łódzkiej, Łódź (in Polish).
- [6] Wasilewski, P. (1993). Silumins – Modification and its effect on structure and properties, PAN Krzepnięcie metali i stopów, Zeszyt 21, Monografia, Katowice (in Polish).
- [7] Ciućka, T. (2005). Registration of crystallization of AlSi20CuNiAK20 casting alloy with ATND method. Archives of Foundry Engineering R. 5 nr 17 ) (pp. 45-50).
- [8] Ciućka, T. (2006). Crystallization curves of syntetic casting alloy on base of aluminum AlCu7Ni5Fe3. Archives of Foundry Engineering (pp. 49-54).
- [9] Ciućka, T. (2006). Registration of crystallization of AG51 (AlMg5Si1) casting alloy with ATND method. Archives of Foundry Engineering R. 6 nr 18 (pp. 191-196).
- [10] Binczyk, F. Śleziona, J. (2010). Effect of modyfication on the properties of IN-713C alloy. Archives of Foundry Engineering (pp. 9-12).
- [11] Krajewski, W.K., Zak, P.L. Orava, J. Greer,A.L. Krajewski, P.K. (2012). Structural stability of the high-aluminium zinc alloys modified with Ti addition. Archives of Foundry Engineering. (61-66).
- [12] Medlen, D. Bolibruchova, D. (2012) The influence of remelting on the properties of AlSi6Cu4 alloy modified by antimony. Archives of Foundry Engineering. (81-86).
- [13] Walasek, A. Szajnar, J. (2012). The mechanism of the surface alloy layer creation for cast steel. Archives of Foundry Engineering. (115-118).
- [14] Ignaszak, Z. (2011). Contribution to determination of the life time of chemically self-hardening mould sand.Archives of Foundry Engineering. (55-57).
- [15] Pezda, J. (2011). Predicting of mechanical properties of EN AB-46000 alloy subjected to dispersion hardening. Archives of Foundry Engineering. (103-108).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-bb3ad5bf-b629-4b92-a82d-5de0e5b757fd