Issue 30

R. Baptista et alii, Frattura ed Integrità Strutturale, 30 (2014) 118-126; DOI: 10.3221/IGF-ESIS.30.16 126 [2] Cláudio, R. A., Freitas, M., Reis, L., Li, B., Guelho, I., Multiaxial Fatigue Behaviour of 1050 H14 Aluminium Alloy by a Biaxial Cruciform Specimen Testing Method, In: 10th Int. Conf. Multiaxial Fatigue Fract., (2013). [3] Cláudio, R., Freitas, A. M., Reis, L., Li, B., Guelho, I., Antunes, V., Maia, J., In-plane biaxial fatigue testing machine powered by linear iron core motors, Sixth Symp. Appl. Autom. Technol. Fatigue Fract. Test. Anal., ASTM STP 1571 (2013). [4] Hanabusa, Y., Takizawa, H., Kuwabara, T., Numerical verification of a biaxial tensile test method using a cruciform specimen, J. Mater. Process. Technol., 213(6) (2013) 961–970. [5] Müller W., Pöhlandt, K., New experiments for determining yield loci of sheet metal, J. Mater. Process. Technol., 60(I 996) (1996) 643–648. [6] Bruschi, S., Altan, T., Banabic, D., Bariani, P. F., Brosius, A., Cao, J., Ghiotti, A., Khraisheh, M., Merklein, M., Tekkaya, A. E., Testing and modelling of material behaviour and formability in sheet metal forming, CIRP Ann. - Manuf. Technol. (2014). [7] Leotoing, L., Guines, D., Zidane, I., Ragneau, E., Cruciform shape benefits for experimental and numerical evaluation of sheet metal formability, J. Mater. Process. Technol., 213(6) (2013) 856–863. [8] Yu, Y., Wan, M., Wu, X.-D., Zhou, X.-B., Design of a cruciform biaxial tensile specimen for limit strain analysis by FEM, J. Mater. Process. Technol., 123(1) (2002) 67–70. [9] Smits, A., Van Hemelrijck, D., Philippidis, T. P., Cardon, A., Design of a cruciform specimen for biaxial testing of fibre reinforced composite laminates, Compos. Sci. Technol., 66(7–8) (2006) 964–975. [10] Makris, A., Vandenbergh, T., Ramault, C., Van Hemelrijck, D., Lamkanfi, E., Van Paepegem, W., Shape optimisation of a biaxially loaded cruciform specimen, Polym. Test., 29(2) (2010) 216–223. [11] Guelho, I., Reis, L., Freitas, M., Li, B., Madeira, J. F. A., Cláudio, R. A., Optimization of Cruciform Specimen for a Low Capacity Biaxial Testing Machine, In: 10th Int. Conf. Multiaxial Fatigue Fract., (2013). [12] Poncelet, M., Barbier, G., Raka, B., Courtin, S., Desmorat, R., Le-Roux, J. C., Vincent, L., Biaxial High Cycle Fatigue of a type 304L stainless steel: Cyclic strains and crack initiation detection by digital image correlation, Eur. J. Mech. - A/Solids, 29(5) (2010) 810–825. [13] Ackermann, S., Kulawinski, D., Henkel, S., Biermann, H., Biaxial in-phase and out-of-phase cyclic deformation and fatigue behavior of an austenitic TRIP steel, Int. J. Fatigue, 67 (2014) 123–133. [14] Lamkanfi, E., Van Paepegem, W., Degrieck, J., Ramault, C., Makris, A., Van Hemelrijck, D., Strain distribution in cruciform specimens subjected to biaxial loading conditions. Part 1: Two-dimensional versus three-dimensional finite element model, Polym. Test., 29(1) (2010) 7–13. [15] Makinde, A., Thibodeau, L., Neale, K., Development of an apparatus for biaxial testing using cruciform specimens, Exp. Mech., 32(2) (1992) 138–144. [16] O. for Standardization, ISO 3, Preferred numbers — Series of preferred numbers, (1973). [17] Custódio, A.L., Madeira, J.F.A., Vaz, A.I.F., Vicente, L.N., Direct multisearch for multiobjective optimization, J. Optim., (2011) 1–33.