Issue 47

L. Marsavina et al., Frattura ed Integrità Strutturale, 47 (2019) 266-276; DOI: 10.3221/IGF-ESIS.47.20 276 [35] Belrhiti, Y., Dupre, J.C., Pop, O., Germaneau, A., Doumalin, P., Huger, M and, Chotard, T. Combination of Brazilian test and digital image correlation for mechanical characterization of refractory materials (2017) Journal of the European Ceramic Society, 37 (5), 2285-2293. [36] Bourdin, F., Stinville, J.C., Echlin, M.P., Callahan, P.G., Lenthe, W.C., Torbet, C.J., Texier, D., Bridier, F., Cormier, J., Villechaise, P., Pollock, T.M. and Valle, V. (2018) Measurements of plastic localization by heaviside-digital image correlation, Acta Materialia, 157, 307-325. [37] Valle, V., Bokam, P., Germaneau, A. and Hedan, S. (2018) New Development of Digital Volume Correlation for the Study of Fractured Materials, Experimental Mechanics, 1-15. Article in Press. [38] Brémand, F., Cottron, M., Doumalin, P., Dupré, J.C., Germaneau, A., Valle, V. Mesures en mécanique par méthodes optiques, Techniques de l’Ingénieur, R1850 V2, 1-26. [39] Belrhiti, Y., Gallet-Doncieux, A., Germaneau, A., Doumalin, P., Dupre, J.C., Alzina, A., Michaud, P., Pop, I.O., Huger, M., Chotard, T. (2012) Application of optical methods to investigate the non-linear asymmetric behavior of ceramics exhibiting large strain to rupture by four-points bending test, Journal of the European Ceramic Society, 32, 4073-4081. [40] EN 310:1993. Wood-based panels. Determination of modulus of elasticity in bending and of bending strength. [41] Linul, E., Marsavina, L., Sadowski T., Kneć, M. (2012) Size effect on fracture toughness of rigid polyurethane foams, Solid State Phenomena, 188, 205-210. [42] Marsavina, L. and Linul, E., Fracture toughness of polyurethane foams. Experimental versus micromechanical models, 18th European Conference on Fracture: Fracture of Materials and Structures from Micro to Macro Scale, ECF 2010; Dresden; Germany; 30 August - 3 September 2010; Code 93905 [43] Marsavina, L., Constantinescu, D.M., Linul, E. et al. (2015) Shear and mode II fracture of PUR foams, Engineering Failure Analysis, 58, 465-476. [44] Petrova, V., Marsavina, L., Sadowski, T. (2012). Revisit of compact mode II crack specimen. Analysis and fracture interpretation, Theoretical and Applied Fracture Mechanics, 59(1), pp. 41-48. [45] Aliha, M.R.M., Linul, E., Bahmani, A., Marsavina, L. (2018) Experimental and theoretical fracture toughness investigation of PUR foams under mixed mode I+III loading, Polymer Testing, 67, pp. 75-83. [46] Erdogan, F., Sih, G.C. (1963). On the crack extension in plates under plane loading and transverse shear, Journal of Basic Engineering, 85, pp. 519-525. [47] Marsavina, L., Constantinescu, D.M., Linul, E., Stuparu, F.A., Apostol, D.A. (2016) Experimental and numerical crack paths in PUR foams, Engineering Fracture Mechanics, 167, pp. 68-83. [48] Hussain, M.A., Pu, S.L., Underwood J. (1974) Strain energy release rate for a crack under combined mode I and mode II. In: Fracture analysis, Paris PC, G.R. Irwin GR Editors, ASTM STP560, Philadelphia, pp. 2-28. [49] Sih, G.C. (1974). Strain-energy-density factor applied to mixed mode crack problems, International Journal of Fracture, 10, pp. 305-321. [50] Marsavina, L., Berto, F., Negru, R., Serban, D.A., Linul, E. (2017) An engineering approach to predict mixed mode fracture of PUR foams based on ASED and micromechanical modeling, Theoretical and Applied Fracture Mechanics, 91, pp. 148-154. [51] Hild, F. and Roux, S. (2006) Measuring stress intensity factors with a camera: integrated digital image correlation (I- DIC), Comptes Rendus Mécanique, 334, 8–12. [52] Jamaaoui, A., Pop, O., Ktari, R., Millien, A. and Petit, C. (2017) Analyzing of wedge splitting test on asphalt pavement using optical measurements, Journal of Testing and Evaluation, 45 (6), 1959-1970 [53] Williams, M. (1957) On the stress distribution at the base of a stationary crack, ASME Journal Applied Mechanics 24, 109-114. [54] Muskhelishvili, IN. (1933) Some basic problem of mathematical theory of elasticity, English translation, Noordhoff.