Dialogue essais-simulation et identification de lois de comportement ...
Dialogue essais-simulation et identification de lois de comportement ... Dialogue essais-simulation et identification de lois de comportement ...
Partie A – Chapitre 2 : Caractérisation du comportement sous chargement biaxial (Doyoyo et Wierzbicki 2003) Doyoyo M.et Wierzbicki T. (2003). Experimental studies on the yield behavior of ductile and brittle aluminum foams. International Journal of Plasticity 19, 1195-1214. (El-hajjar et Haj-Ali 2004) El-Hajjar R., Haj-Ali R. (2004). In-plane shear testing of thick-section pultruded FRP composites using a modified Arcan fixture, Composites Part B 35, 421-428. (Ferron et Makinde 1988) Ferron G. et Makinde A. (1988). Design and development of a biaxial strength testing device. Journal of Testing Evaluation, 16, 253-256. (Gall et al. 1998) Gall K., Jacobus K., Sehitoglu H.et Maier H.J (1998). Stress-induced martensitic phase transformations in polycrystalline CuZnAl shape memory alloys under different stress states. Metallurgical and Materials Transactions A 29, 765-773. (Grolleau et al. 2009) Grolleau V., Louche H., Penin A., Chauvelon P., Rio G., Liu Y., Favier D. (2009). Bulge tests on ferroelastic and superelastic NiTi sheets with full field thermal and 3D-kinematical measurements: experiments and modelling. ESOMAT 2009, 06011. pastel-00910076, version 1 - 27 Nov 2013 (Grolleau et al. 2011) Grolleau V., Louche H., Delobelle V., Penin A., Rio G., Liu Y., Favier D. (2011). Assessment of tension–compression asymmetry of NiTi using circular bulge testing of thin plates. Scripta Materialia 65, 347–350. (Hannon et Tierman 2008) Hannon A.et Tiernan P. (2008). A review of planar biaxial tensile test systems for sheet metal. Journal of Materials Processing Technology 198, 1-13. (Kuwabara 2007) Kuwabara T. (2007). Advances in experiments on metal sheets and tubes in support of constitutive modeling and forming simulations. International Journal of Plasticity 23, 385-419. (Lecompte et al. 2007) Lecompte D., Smits A., Sol H., Vantomme J. et Hemelrijck D. V. (2007). Mixed numerical–experimental technique for orthotropic parameter identification using biaxial tensile tests on cruciform specimens. International Journal of Solids and Structures 44, 1643-1656. (Lexcellent et al. 2002) Lexcellent C., Vivet A., Bouvet C., Calloch S. et Blanc, P. (2002). Experimental and numerical determinations of the initial surface of phase transformation under biaxial loading in some polycrystalline shape-memory alloys. J. Mech.and Phys. of Solids 50, 2717–2735. (Machado et al. 2012) Machado G., Chagnon G.et Favier D. (2012). Induced anisotropy by the Mullins effect in filled silicone rubber. Mechanics of Materials 50, 70-80. (Mohr et Ebnoether 2009) Mohr D.et Ebnoether F. (2009). Plasticity and fracture of martensitic boron steel under plane stress conditions. International Journal of Solids and Structures 46, 3535-3547. (Mohr et Jacquemin 2008) Mohr D. et Jacquemin J. (2008). Large deformation of anisotropic austenitic stainless steel sheets at room temperature: Multiaxial experiments and phenomenological modeling. Journal of the Mechanics and Physics of Solids 56, 2935-2956. (Mohr et Oswald 2008) Mohr D. et Oswald M. (2008). A new experimental technique for the multiaxial testing of advanced high strength steel sheets. Experimental Mechanics 48(1), 65-77. (Pottier et al. 2012) Pottier T., Vacher P., Toussaint F., Louche H., & Coudert T. (2012). Out-of-plane testing procedure for inverse identification purpose: application in sheet metal plasticity. Experimental mechanics, 52(7), 951-963. 52
Partie A – Chapitre 2 : Caractérisation du comportement sous chargement biaxial (Rogueda et al. 1996) Rogueda C., Lexcellent C., Bocher L., (1996). Experimental study of seudoelastic behaviour of a Cu-Zn-Al polycrystalline shape memory alloy under tension–torsion proportional and non-proportional loading tests. Archives of Mechanics 48 (5), 1025–1045. (Smits et al. 2006) Smits A., Van Hemelrijck D., Philippidis T.P. et Cardon A. (2006). Design of a cruciform specimen for biaxial testing of fibre reinforced composite laminates. Composites Science and Technology 66, 964-975. (Sun et Li 2002) Sun Q.-P., Li Z.-Q. (2002). Phase transformation in superelastic NiTi polycrystalline micro-tubes under tension and torsion–from localization to homogeneous deformation. International Journal of Solids and Structures 39, 3797–3809. (Taillard et al. 2008) Taillard K., Arbab Chirani S., Calloch S., Lexcellent C. (2008). Equivalent transformation strain and its relation with martensite volume fraction for isotropic and anisotropic shape memory alloys. Mechanics of Materials 40, 151–170. pastel-00910076, version 1 - 27 Nov 2013 (Tasan et Hoefnagels 2012) Tasan C.C. et Hoefnagels J.P.M. (2012). Multiaxial deformation setup for microscopic testing of sheet metal to fracture. Experimental Mechanics 52, 669–678. (Teaca 2009) Teaca M. (2009). Caractérisation expérimentale et modélisation de la déformation plastique des tôles métalliques. Thèse de doctorat, Université de Metz. (Terriault et al. 2003) Terriault P., Settouane K. et Brailovski V. (2003). Biaxial testing at different temperatures of cruciform TI–NI samples. Proceeding of the internatonal conference on Shape Memory and Superelastic Technologies, California, 247-257. (Vogler et Kyriakides 1999) Vogler T.J. et Kyriakides S. (1999). Inelastic behavior of an AS4/PEEK composite under combined transverse compression and shear. Part I: experiments, International Journal of Plasticity 15, 783-806. (Wang et al. 2010) Wang X.M., Wang Y.F., Lu Z.Z., Deng C.H. et Yue Z.F. (2010). An experimental study of the superelastic behavior in NiTi shape memory alloys under biaxial proportional and nonproportional cyclic loadings. Mechanics of Materials 42, 365–373. (Wang et al. 2007) Wang Y.F., Yue Z.F. et Wang J. (2007). Experimental and numerical study of the superelastic behaviour on NiTi thin-walled tube under biaxial loading. Computational Materials Science 40, 246–254. 53
- Page 9 and 10: Introduction générale Introductio
- Page 11 and 12: Introduction générale Le second c
- Page 13 and 14: Partie A - Chapitre 1 : Superélast
- Page 15 and 16: Partie A - Chapitre 1 : Superélast
- Page 17 and 18: Partie A - Chapitre 1 : Superélast
- Page 19 and 20: Partie A - Chapitre 1 : Superélast
- Page 21 and 22: Partie A - Chapitre 1 : Superélast
- Page 23 and 24: Partie A - Chapitre 1 : Superélast
- Page 25 and 26: Partie A - Chapitre 1 : Superélast
- Page 27 and 28: Partie A - Chapitre 1 : Superélast
- Page 29 and 30: Partie A - Chapitre 1 : Superélast
- Page 31 and 32: Partie A - Chapitre 1 : Superélast
- Page 33 and 34: Partie A - Chapitre 1 : Superélast
- Page 35 and 36: Partie A - Chapitre 2 : Caractéris
- Page 37 and 38: Partie A - Chapitre 2 : Caractéris
- Page 39 and 40: Partie A - Chapitre 2 : Caractéris
- Page 41 and 42: Partie A - Chapitre 2 : Caractéris
- Page 43 and 44: Partie A - Chapitre 2 : Caractéris
- Page 45 and 46: Partie A - Chapitre 2 : Caractéris
- Page 47 and 48: Partie A - Chapitre 2 : Caractéris
- Page 49 and 50: Partie A - Chapitre 2 : Caractéris
- Page 51 and 52: Partie A - Chapitre 2 : Caractéris
- Page 53 and 54: Partie A - Chapitre 2 : Caractéris
- Page 55 and 56: Partie A - Chapitre 2 : Caractéris
- Page 57 and 58: Partie A - Chapitre 2 : Caractéris
- Page 59: Partie A - Chapitre 2 : Caractéris
- Page 63 and 64: Partie A - Chapitre 3 : Procédures
- Page 65 and 66: Partie A - Chapitre 3 : Procédures
- Page 67 and 68: Partie A - Chapitre 3 : Procédures
- Page 69 and 70: Partie A - Chapitre 3 : Procédures
- Page 71 and 72: Partie A - Chapitre 3 : Procédures
- Page 73 and 74: Partie A - Chapitre 3 : Procédures
- Page 75 and 76: Partie A - Chapitre 3 : Procédures
- Page 77 and 78: Partie A - Chapitre 3 : Procédures
- Page 79 and 80: Partie A - Chapitre 3 : Procédures
- Page 81 and 82: Partie A - Chapitre 3 : Procédures
- Page 83 and 84: Partie A - Chapitre 3 : Procédures
- Page 85 and 86: Partie A - Chapitre 3 : Procédures
- Page 87 and 88: Partie A - Chapitre 3 : Procédures
- Page 89 and 90: Partie A - Chapitre 3 : Procédures
- Page 91 and 92: Partie A - Chapitre 3 : Procédures
- Page 93 and 94: Partie A - Chapitre 4 : Résultats
- Page 95 and 96: Partie A - Chapitre 4 : Résultats
- Page 97 and 98: Contrainte MPa Partie A - Chapitre
- Page 99 and 100: Contrainte MPa Contrainte (MPa) Par
- Page 101 and 102: Contrainte MPa Contrainte MPa Parti
- Page 103 and 104: Force (kN) Partie A - Chapitre 4 :
- Page 105 and 106: Partie A - Chapitre 4 : Résultats
- Page 107 and 108: Partie A - Chapitre 4 : Résultats
- Page 109 and 110: Déformation Force (kN) Partie A -
Partie A – Chapitre 2 : Caractérisation du <strong>comportement</strong> sous chargement biaxial<br />
(Rogueda <strong>et</strong> al. 1996) Rogueda C., Lexcellent C., Bocher L., (1996). Experimental study of seudoelastic<br />
behaviour of a Cu-Zn-Al polycrystalline shape memory alloy un<strong>de</strong>r tension–torsion proportional and<br />
non-proportional loading tests. Archives of Mechanics 48 (5), 1025–1045.<br />
(Smits <strong>et</strong> al. 2006) Smits A., Van Hemelrijck D., Philippidis T.P. <strong>et</strong> Cardon A. (2006). Design of a<br />
cruciform specimen for biaxial testing of fibre reinforced composite laminates. Composites Science<br />
and Technology 66, 964-975.<br />
(Sun <strong>et</strong> Li 2002) Sun Q.-P., Li Z.-Q. (2002). Phase transformation in superelastic NiTi polycrystalline<br />
micro-tubes un<strong>de</strong>r tension and torsion–from localization to homogeneous <strong>de</strong>formation. International<br />
Journal of Solids and Structures 39, 3797–3809.<br />
(Taillard <strong>et</strong> al. 2008) Taillard K., Arbab Chirani S., Calloch S., Lexcellent C. (2008). Equivalent<br />
transformation strain and its relation with martensite volume fraction for isotropic and anisotropic<br />
shape memory alloys. Mechanics of Materials 40, 151–170.<br />
pastel-00910076, version 1 - 27 Nov 2013<br />
(Tasan <strong>et</strong> Hoefnagels 2012) Tasan C.C. <strong>et</strong> Hoefnagels J.P.M. (2012). Multiaxial <strong>de</strong>formation s<strong>et</strong>up for<br />
microscopic testing of she<strong>et</strong> m<strong>et</strong>al to fracture. Experimental Mechanics 52, 669–678.<br />
(Teaca 2009) Teaca M. (2009). Caractérisation expérimentale <strong>et</strong> modélisation <strong>de</strong> la déformation<br />
plastique <strong>de</strong>s tôles métalliques. Thèse <strong>de</strong> doctorat, Université <strong>de</strong> M<strong>et</strong>z.<br />
(Terriault <strong>et</strong> al. 2003) Terriault P., S<strong>et</strong>touane K. <strong>et</strong> Brailovski V. (2003). Biaxial testing at different<br />
temperatures of cruciform TI–NI samples. Proceeding of the internatonal conference on Shape<br />
Memory and Superelastic Technologies, California, 247-257.<br />
(Vogler <strong>et</strong> Kyriaki<strong>de</strong>s 1999) Vogler T.J. <strong>et</strong> Kyriaki<strong>de</strong>s S. (1999). Inelastic behavior of an AS4/PEEK<br />
composite un<strong>de</strong>r combined transverse compression and shear. Part I: experiments, International<br />
Journal of Plasticity 15, 783-806.<br />
(Wang <strong>et</strong> al. 2010) Wang X.M., Wang Y.F., Lu Z.Z., Deng C.H. <strong>et</strong> Yue Z.F. (2010). An experimental<br />
study of the superelastic behavior in NiTi shape memory alloys un<strong>de</strong>r biaxial proportional and nonproportional<br />
cyclic loadings. Mechanics of Materials 42, 365–373.<br />
(Wang <strong>et</strong> al. 2007) Wang Y.F., Yue Z.F. <strong>et</strong> Wang J. (2007). Experimental and numerical study of the<br />
superelastic behaviour on NiTi thin-walled tube un<strong>de</strong>r biaxial loading. Computational Materials<br />
Science 40, 246–254.<br />
53
Change language