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Purpose: The main aim of the present study was to analyze the influence of the thermal fatigue on the AISI H13 die surface during the aluminium high pressure die casting process. Design/methodology/approach: Two different gradients of temperature were considered (ΔT = 200 and 250°C). The thermal stresses were obtained through computer numerical analysis - Finite Element Method. Then an analytical study, through the equation of Basquin, was conducted to determine the number of cycles until the die failure. Findings: Taking in account the divergences found in the solutions for determining the number of life cycles to die failure and guided by technical data and commercial experience of life cycles for the AISI H13 steel it was possible to propose coefficients of correction for the equation of Basquin. Research limitations/implications: It should be highlighted that the use of the proposed corrected coefficients for the Basquin equation can show a satisfactory results related to the practice - valid only for similar conditions of this work. Practical implications: The behavior of the steel used for the dies are dependent of the temperature and density, elastic modulus, Poisson’s ratio, coefficient of thermal expansion, hardness, thermal conductivity and yield strength and an incorrect steel selection can lead to thermal stresses amplitude favorable for the onset of the cracks. Originality/value: The dies play an important role in the aluminium high pressure die casting process. During the die manufacturing process the die design and the steels behavior are a major concern on efficient manufacturing, i.e. related to maximize the life cycle. During the injection process the thermal fatigue is one of the responsible factor of onset of cracks - estimated to be approximately 80%.
Słowa kluczowe
Wydawca
Rocznik
Tom
Strony
439--445
Opis fizyczny
Bibliogr. 21 poz., rys., tab.
Twórcy
autor
- Mechanical Department, Universidade Federal do Paraná, Av. Cel. Francisco H. dos Santos, 210, CEP 81531-990, Curitiba - Paraná - Brazil
autor
- Mechanical Department, Universidade Federal do Paraná, Av. Cel. Francisco H. dos Santos, 210, CEP 81531-990, Curitiba - Paraná - Brazil
autor
- Mechanical Department, Universidade Federal do Paraná, Av. Cel. Francisco H. dos Santos, 210, CEP 81531-990, Curitiba - Paraná - Brazil
Bibliografia
- [1] D. Klobcar, B. Tusek, B. Taljat, Thermal fatigue of materials for die-casting tooling, Materials Science and Engineering A 472/1-2 (2008) 198-207.
- [2] Y. Wang, A study of PVD coatings and die materials for extended die casting die life, Surfaces and Coatings Technology 94-95 (1997) 60-63.
- [3] X. Hu, Thermal fatigue behaviour of niobium microalloyed H13 steel, Journal of Shanghai University (English Edition) 10/4 (2006) 375-376.
- [4] J. Lin, A.O. Kunrath, D. Zhong, S. Meyres, B. Mishra, J.J. Moore, Development of multi-layered and graded die coatings for materials processing applications, Advances in Science and Technology 45 (2006) 1145-1154.
- [5] S.N. Aqida, F. Calosso, D. Brabazon, S. Naher, M. Rosso, Thermal Fatigue properties of laser treated steels at semisolid processing temperatur, The International Journal of Material Forming 3/1 (2010) 797-800.
- [6] A.R. Tassin, Technology of pressure die casting, aluminum its alloys and zamak, Molds Design, Brazil, 1995 (in Portuguese).
- [7] S. Ott, M.D. Diehl, Study of the influence of molybdenum percentage on the thermal fatigue resistance of vermicularis cast iron, Proceeding of the 53° Congress Anual ABM, Brazil, 1997 (in Portuguese).
- [8] A. Fissolo, C. Robertson, V. Maillot, Prediction of crack initiation and growth under thermal fatigue, Chapter 3, Thermomechanical Fatigue and Fracture, M.H. Aliabadi (Ed.),WIT Press, Southampton, 2002.
- [9] A. Persson, S. Hogmark, J. Bergstrom, Thermal fatigue cracking of surface engineered hot work tool steels, Surface and Coating Technology 191 (2005) 216-227.
- [10] X.C. Wu, W.Y. Peng, Y.A. Min, Study on thermal fatigue behavior of boride layer of H13 steel, Materials Science Forum 475 (2004) 249-252.
- [11] R.A. Mesquita, L.C. França, C.A. Barbosa, Cases of application of new tool steels for hot work, Tecnologia em Metalurgia e Materiais 2 (2005) 70-75 (in Portuguese).
- [12] Villares Metals, Stainless steel for molds, H13 villares tool steels, Technical Catalog 1a, Brazil, 2007 (in Portuguese).
- [13] S. Suresh, Fatigue of material, Cambridge solid state science series, Paperback, USA,1998.
- [14] R.B. Magnabosco, Fatigue life of carbon steel with ferrite-martensite biphasic structure, Proceeding of the 14° Congresso Brasileiro de Engenharia e Ciencia dos Materiais Brazil, 2000 (in Portuguese).
- [15] M.A. Meyers, K.K. Chawla, Mechanical behavior of materials, Cambridge University Press, New York, 1999.
- [16] N. Cappetti, L. Garofalo, A. Naddeo, M. Nastasia, A. Pellegrino, A method for setting variables in Super Plastic Forming process, Journal of Achievements in Materials and Manufacturing Engineering 38/2 (2010) 187-194.
- [17] A. Śliwa, L.A. Dobrzański, W. Kwaśny, M. Staszuk, Simulation of the microhardness and internal stresses measurement of PVD coatings by use of FEM, Journal of Achievements in Materials and Manufacturing Engineering 43/2 (2010) 684-691.
- [18] M.J. Jackson, Numerical analysis of small recessed silicon carbide grinding wheels, Journal of Achievements in Materials and Manufacturing Engineering 43/1 (2010) 27-37.
- [19] W. Kapturkiewicz, A.A. Burbelko, E. Fras, M. Górny, D. Gurgul, Computer modelling of ductile iron solidification using FDM and CA methods, Journal of Achievements in Materials and Manufacturing Engineering 43/1 (2010) 310-323.
- [20] Abaqus/CAE, User’s Manual, Version 6.9, 2009.
- [21] http://www.SCHMOLZ-BICKENBACH.com.br/produtos/trabalho-a-quente.html, 2010.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-6c2c6fe0-6615-41ac-a0e6-62a5009225e8