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A review on recent developments of Marciniak-Kuczynski model

Autorzy
Banabic D.
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
PL
Przegląd najnowszych osiągnięć w zakresie zastosowań modelu Marciniak-Kuczynski - hołd dla profesora Marciniaka
Języki publikacji
EN
Abstrakty
EN
First, the author contributed with some aspects concerning the chronology of the developments of the Marciniak model. A review of the recent developments in the last decade of Marciniak-Kuczynski model is presented in the paper. Implementation of the new constitutive and polycrystalline models, enhancing the existing models to take into account new material, process parameters and strain-paths, modeling the Forming Limit Band concept are briefly reviewed. Capabilities of some commercial programs specially designed for the computation of forming limit curves (FLC) are also analyzed.
PL
W pierwszej części pracy przedstawione są chronologicznie ostatnie osiągnięcia w zastosowaniach modelu Marciniak-Kuczynski. Następnie zaprezentowany jest przegląd prac z tej tematyki opublikowanych w ostatniej dekadzie. Omówiono nowe prawa konstytutywne i modele polikryształów wzbogacające istniejące modele poprzez uwzględnienie nowych materiałów i parametrów procesu, zmian drogi odkształcenia, a także poprzez wprowadzenie koncepcji pasma odkształceń granicznych (ang. Forming Limit Band - FLB). W pracy przedstawiono również ocenę możliwości różnych programów specjalnie dedykowanych do wyznaczania krzywych odkształcalności granicznej (ang. forming limit curves - FLC).
Słowa kluczowe
EN
Wydawca
Wydawnictwa AGH
Czasopismo
Computer Methods in Materials Science
Rocznik
2010
Tom
Vol. 10, No. 4
Strony
225--237
Opis fizyczny
Bibliogr. 169 poz., rys.
Twórcy
autor
Banabic D.
  • CERTETA - Research Centre on Sheet Metal Forming Technical Universityof Cluj Napoca Cluj Napoca, Romania, banabic@tcm.utcluj.ro
Bibliografia
  • Abedrabbo, N., Pourboghrat, F., Carsley, J., 2006, Forming of aluminum alloys at elevated temperatures, Int. J. Plasticity, 22,314-373.
  • Ahmadi, S., Eivani, A.R., Akbarzadeh, A., 2009, An experimental and theoretical study on the prediction of Forming Limit Diagrams using new BBC yield criteria and M-K analysis, Computational Materials Science, 44, 1272-1280.
  • Allwood, J.M., Shouler, D.R, Tekkaya, A.E., 2007, The increased forming limits of incremental sheet forming processes, Key Engineering Materials, 344, 621 -628.
  • Allwood, J.M., Shouler, D.R., 2008, Generalised forming limit diagrams showing increased forming limits with non-planar stress states, International Journal of Plasticity, 25, 1207-1230.
  • Aretz, Ft., 2004, Numerical restrictions of the modified maximum force criterion for prediction of forming limits in sheet metal forming, Modelling Simul. Mater. Sci. Eng., 12, 677-692.
  • Aretz, H., 2006, Impact of the equibiaxial plastic strain ratio on the FLD prediction, Proc. 9th ESAFORM Conference on Material Forming. Glasgow, eds, Juster, N., Rosochowski, A., AKAPIT, Krakow, 311-314.
  • Asaro, R.J., Needleman, A., 1985, Texture development and strain hardening in rate-dependent polycrystals, Acta Metall,. 33, 923-953.
  • Azrin, M., Backofen, W.A., 1970, The deformation and failure of a biaxially stretched sheet, Metall. Trans., 1, 2857-2861.
  • Banabic, D., 1999, Limit strains in the sheet metals by using the 1993 Hill's yield criterion, J. Materials Process. Techn,. 92-93, 429-432.
  • Banabic, D., 2000a, Forming Limits of Sheet Metals, Formability of Metallic Materials, ed., Banabic, D., Springer-Verlag, Berlin, Heidelberg, New York, 173-215.
  • Banabic, D., 2000b, Theoretical Models of the FLD's, Form-ability of Metallic Materials, ed., Banabic, Springer-Verlag, Berlin Heidelberg New York, 317-327.
  • Banabic, D., Dannenmann, E., 2001, The influence of the yield locus shape on the limits strains, J. Materials Process. Techn., 109, 9-12.
  • Banabic, D., Kuwabara, T., Balan, T., Comsa, D.S., Mean, D., 2003, Non-quadratic yield criterion for orthotropic sheet metals under plane-stress conditions, Int. J. Mech. Sci., 45,797-811.
  • Banabic, D., Comsa, S.D., Jurco, P., Cosovici, G., Paraianu, L., Julean, D., 2004a, FLD theoretical model using a new anisotropic yield criterion, J. Materials Process. Techn., 157-158, 23-27.
  • Banabic, D., Comsa, S.D., Jurco, P., Wagner, S., He, S., Van Houtte, P., 2004b, Prediction of FLC from two anisotropic constitutive models, Proc. 7th ESAFORM Conference on Material Forming, ed., Stören, S., Trondheim, 455-459.
  • Banabic, D., 2004, Anisotropy and formability of AA5182-0 aluminium alloy sheets, Annales of CIRP, 53, 219-222.
  • Banabic, D., Aretz, H., Comsa, D.S., Paraianu, L., 2005a, An improved analytical description of orthotropy in metallic sheets, Int. J. Plasticity, 21, 493-512.
  • Banabic, D., Cazacu, O., Paraianu, L., Jurco, P., 2005b, Recent Developments in the Formability of Aluminum Alloys, Proc. of the NUMISHEET 2005 Conference, eds, Smith, L.M., Pourboghrat, F., Yoon, J.-W., Stoughton, T.B., 466-472.
  • Banabic, D., 2006, Numerical prediction of FLC using the M-K-Model combined with advanced material models, Numerical and experimental methods in prediction of forming limits in sheet forming and tube hydroforming processes, ed., Hora, P., ETH Zürich, Zürich, 37-42.
  • Banabic, D., Vos, M., 2007, Increasing the robustness in the simulation of sheet metal forming processes using a new concept - Forming Limit Band, Annales of CIRP, 56, 249-252.
  • Banabic, D., Barlat, F., Cazacu, O., Kuwabara T., 2007, Anisotropy and formability, Advances in Material Forming-ESAFORM 10 Years on, eds, Chinesta, F., Cueto, E., Springer, Heidelberg-Berlin, 143-173.
  • Banabic, D., Soare, S., 2008, On the effect of the normal pressure upon the forming limit strains, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 199-204.
  • Banabic, D., Barlat, F., Cazacu, O., Kuwabara, T., 2010a, Advances in anisotropy and formability, Int. J. Mater. Form.,3, 165-189.
  • Banabic, D., Dragos, G., Bichis, I., 2010b, Influence of variability of mechanical data on Forming Limits Curves, Steel Research International, 81, 1356-1360.
  • Banabic, D., 2010, Sheet Metal Forming Processes, Springer, Heidelberg.
  • Barata da Rocha, A., Jalinier, J.M., 1984, Plastic instability of sheet metals under simple and complex strain path, Trans. Iron Steel Inst, 24, 133-140.
  • Barata da Rocha, A., Barlat, F., Jalinier, J.M., 1985, Prediction of the forming limit diagrams of anisotropic sheets in linear and non-linear loading, Mat. Sci. Eng., 68, 151-164.
  • Barlat, F., Richmond, O., 1985, Prediction of tricomponent plane stress yield surfaces and associated flow and failure behavior of strongly textured FCC sheets. Mat. Sci. Eng., 95, 15-29.
  • Barlat, F., 1987, Crystallographic texture, anisotropic yield surfaces and forming limits of sheet metals, Mat. Sci. Eng., 91, 55-72.
  • Barlat, F., Lian, J., 1989, Plastic Behavior and Stretchability of Sheet Metals. Part I: Yield Function for Orthotropic Sheets under Plane Stress Conditions, Int. J. Plasticity, 5,51-66.
  • Barlat, F., Becker, R.C., Hayashida, Y., Maeda, Y., Yanagawa, M., Chung, K, Brem, J.C., Lege, D.J., Matsui, K., Murtha, S.J., Hattori, S., 1997, Yielding description of solution strengthened aluminum alloys, Int. J . Plast., 13, 185-401.
  • Barlat, F., Brem, J.C., Yoon, J.W., Chung, K., Dick, R.E., Lege, D.J., Pourboghrat, F., Choi, S.-H., Chu, E., 2003, Plane stress yield function for aluminum alloy sheet-Part I: Theory, Int. J. Plasticity, 19, 1297-1319.
  • Bate, P., 1984, The prediction of limit strains in steel sheet using a discrete slip plasticity model, Int. J. Mech. Sci., 26, 373-384.
  • Berstad, T., Furu, T., Holmedal, B., Hopperstad, O.S., Lademo, O.F., Nes, E., Pedersen, K.O., 2004, FEM and a micro-structure based work-hardening model used to calculate FLCs, Proc. 7,h ESAFORM Conference on Material Forming, ed., Stören, S., Trondheim, 131-134.
  • Boudeau, N., Gelin J.C., Salhi, S., 1998, Computational prediction of the localized necking in sheet forming based on microstructural material aspects, Computational Materials Science, 11, 45-64.
  • Boudeau, N., Gelin, J.C., 2000, Necking in sheet metal forming. Influence of macroscopic and microscopic properties of materials, Int. J. Mech. Sciences, 42, 2209-2232.
  • Bressan, J.D., Williams, J.A., 1983, The use of a shear instability criterion to predict local necking in sheet metal deformation, Int. J. Mech. Sciences, 25, 155-168.
  • Brunet, M., Morestin, F., Walter, H., 2001, Damage modeling in sheet metals forming processes with experimental validations, Proc. 4th ESAFORM Conference on Material Forming, ed., Habraken, A.M., Liege, 209-212.
  • Brunet, M., Morestin, F., Walter, H., 2002, Anisotropic ductile fracture in sheet metal forming processes using damage theory, Proc. 5th ESAFORM Conference on Material Forming, eds, Pietrzyk, M., Mitura, Z., Kaczmat, J., Krakow, 135-138.
  • Brunet, M., Morestin, F., Walter-Laberre, H., 2005, Failure analysis of anisotropic sheet metals using a non-local plastic damage model, J. Materials Process. Techn., 170, 457-470.
  • Butuc, C, Barata da Rocha, A., Gracio, J.J., Ferreira Duarte, J., 2002a, A more general model for FLD prediction, J. Materials Proc. Techn., 125-126,213-218.
  • Butuc, C, Barata da Rocha, A., Gracio, J.J., Ferreira Duarte, J., Jurco, P., Comsa, D.S., Banabic, D., 2002b, Influence of constitutive equations and strain-path change on the forming limit diagram for 5182 aluminum alloy, Proc. 5th ESAFORM Conference on Material Forming, eds. Pietrzyk, M., Mitura, Z., Kaczmat, J., Kraków, 715-719.
  • Butuc, C, Gracio, J.J., Barata da Rocha, A., 2003, A theoretical study on forming limit diagrams prediction, J. Material Proc. Techn., 142, 714-724.
  • Butuc, C, Gracio, J.J., Barata da Rocha, A., 2005, Application of the YLD 96 yield criterion on describing the anisotropy and formability of the BCC materials, Proc. 8* ESAFORM Conference on Material Forming, ed.. Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 391-394.
  • Butuc, C, Gracio, J.J., Barata da Rocha, A., 2006, An experimental and theoretical analysis on the application of stress-based forming limit criterion, Int. J. Mech. Sci.. 48,414-429.
  • Cao, J., Yao, H., Karafillis, A., Boyce, M.C., 2000, Prediction of localized thinning in sheet metal using a general anisotropic yield criterion, Int. J. Plasticity, 16, 1105-1129.
  • Carlcer, B., Sigvant, M., 2006, Process Scatter with Respect to Material Scatter, New Developments in Sheet Metal Forming, ed., Liewald, M, Institute for Metal Forming Technology, University of Stuttgart, 225-239.
  • Cazacu, O., Barlat, F., 2001, Generalization of Drucker's yield criterion to orthotropy, Mathematics and Mechanics of Solids, 6, 613-630.
  • Chan, K.C., Tong G.Q., 2003, Formability of high-strain-rate superplastic Al-4.4Cu-l.5Mg/21SiCW, composite under biaxial tension, Material Science Eng., A340. 49-5".
  • Chow, C.L., Yu, L.G., Demeri, M.Y., 1997, A unified damage approach for predicting FLDs, Trans ASME, J. Eng. Materials Techn., 119, 346-353.
  • Chow, C.L., Yang X.J., 2001, Prediction of the FLD on the basis of the damage criterion under non-proportional loading. Proc. Instn. Mechn. Eng., 215C, 405-414.
  • Chow, C.L., Yu, L.G., Tai, W.H., Demeri, M.Y., 2001, Prediction of FLD for AL6111-T4 under non-proportional loading, Int. J. Mech. Sciences, 43, 471-486.
  • Dell, H., Gese, H., Oberhofer, G., 2008, Advanced yield loci and anisotropic hardening in the material model MF GENYLD + CRACHFEM, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 49-54.
  • Dudziński, D., Molinari, A., 1988, Instability of visco-plastic deformation in biaxial loading, C.R. Acad. Sci. Paris. 307, 1315-1321.
  • Evangelista, S.H., Lirani, J., Al-Qureshi, H.A., 2002, Implementing a modified Marciniak-Kuczynki model using the FEM for the simulation of sheet metal deep drawing. J. Materials Process. Techn., 130-131, 135-144.
  • Eyckens, P., Van Bael, A., Van Houtte, P., 2008, An extended Marciniak-Kuczynski forming limit model to assess the influence of Through-Thickness Shear on formability. Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 193-198.
  • Eyckens, P., Van Bael, A., Van Houtte, P., 2009, Marciniak-Kuczynski type modelling of the effect of Through-Thickness Shear on the forming limits of sheet metal. Int. J. Plasticity, 25, 2249-2268.
  • Eyckens, P., Van Bael, A., Van Houtte, P., 2010, An extended Marciniak-Kuczynski model for anisotropic sheet subjected to monotonie strain paths with through-thickness shear, Int. J. Plasticity, 26 (in print).
  • Fjeldbo, S.K., Holmedal, B., Lademo, O.G., Bjerkaas, H., 2005, A numerical study on the onset of plastic instability in extruded materials with strong through-thickness texture variation, Proc. 8th ESAFORM Conference on Material Forming, ed., Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 209-213.
  • Fyllingen, O., Hopperstad, O.S., Lademo, O.F., Langseth, M., 2009, Estimation of forming limit diagrams by the use of the finite element method and Monte Carlo simulation, Computers and Structures, 87, 128-139.
  • Ganjiani, M., Assempour, A., 2007a, An improved analytical approach for determination of FLD considering the effects of yield functions, J. Materials Process. Techn., 182, 598-607.
  • Ganjiani, M., Assempour, A., 2007b, The performance of Karafillis-Boyce yield function on determination of forming limit diagrams, LIE Transactions A: Basics, 20, 55-66.
  • Ganjiani, M., Assempour, A., 2008, Implementation of a robust algorithm for prediction of Forming Limit Diagrams, Journal of Materials Engineering and Performance, 17, 1-6.
  • Ganser, H.P., Werner, E.A., Fisher, F.D., 2000, FLDs: a micro-mechanical approach, Int. J. Mech. Sciences, 42, 2041-2054.
  • Gese, H., Dell, H., 2006, Numerical prediction of FLC with the program CRACH, Numerical and experimental methods in prediction of forming limits in sheet forming and tube hydroforming processes, ed., Hora, P., ETH Zurich, 43-49.
  • Gologanu, M., Leblond, J.B., Perrin, G., 1997, Recent extension of Gurson's model for porous ductile metals, Continuum Micromechanics, ed., Suquet, P., Springer-Verlag, Berlin, Heidelberg, New York, 61-130.
  • Goodwin, G.M., (1968) Application of strain analysis to sheet metal forming problems in the press shop, Society of Automotive Engineers, 680093, 380-387.
  • Gotoh, M., Chung, T., Iwata, N., 1995, Effect of out-of-plane stress on the forming limit strains of sheet metals, JSME International Journal, 38, 123-132.
  • Haddag, B., Abed-Meraim, F., Balan, T., 2008, Strain localization and damage prediction during sheet metal forming, Proc. 11th ESAFORM Conference on Material Forming, Lyon.
  • Han, H.N., Kim, K.H., 2003, A ductile fracture criterion in sheet metal forming process, J. Materials Process. Techn., 142, 231-238.
  • Hecker, S.S., Ghosh, A.K., Gegel, H.L, 1978, Formability: Analysis modeling and experimentation, Met. Soc. of AIME., New York.
  • Hill, R., 1948, A theory of the yielding and plastic flow of anisotropic metals, Proc. Roy. Soc, London, A193, 281-297.
  • Hill, R., 1952, On discontinous plastic states, with special reference to localized necking in thin sheets, J. Mech. Phys. Sol., 1, 19-30.
  • Hill, R., 1979, Theoretical plasticity of textured aggregates, Math. Proc. Cambridge Philos. Soc, 85, 179-191.
  • Hill, R., 1993, A user-friendly theory of orthotropic plasticity in sheet metals, Int. J. Mech. Sci., 35, 19-25.
  • Hiroi T., Nishimura H., 1997, The influence of surface defects on the forming-limit diagram of sheet metal, J. Materials Process. Techn., 72, 102-109.
  • Hiwatashi, S., Van Bael, A., Van Houtte, P., Teodosiu, C, 1998, Prediction of the forming limit strains under strain-path changes: application of an anisotropic model based on texture and dislocation structure, Int. J. Plasticity, 14, 647-669.
  • Hopperstad, O.S., Borvik, T., Bestad, T., Lademo, O.G., 2006, A preliminary numerical study on the influence of PLC on the formability of aluminium alloys, Proc. 9th ESAFORM Conference on Material Forming, eds, Juster,  N.,  Rosochowski,  A.,  Glasgow, AKAPIT, Krakow, 315-318.
  • Hora, P., Tong, L., 1994, Prediction methods for ductile sheet metal failure using FE-simulation, Proc. of the IDDRG Congress, Lisbon, 363-375.
  • Hora, P., Tong, L., Reissner, J., 1996, A prediction method for ductile sheet metal failure, Proc. of the NUMISHEET 1996 Conference, eds, Lee, J.K., Kinzel, G.L., Wagoner, R.H., Dearborn, 252-256.
  • Hora, P., Krauer, J. (eds), 2006, Numerical and experimental methods in prediction of forming limits in sheet metal forming and tube hydroforming processes, FLC-Zurich 06 Conference, Zurich.
  • Hora, P., Merklein, M., Tong, L., Lechler, J., 2007, Numerical and experimental evaluation of thermal dependent FLC. Proc. of the IDDRG 2007 Conference, ed., Tisza, M..Gyor, 23-30.
  • Hora, P., Tong, L., 2008, Theoretical prediction of the influence of curvature and thickness on the FLC by the enhanced modified maximum force criterion, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 205-210.
  • Horstemeyer, M.F., Chiesa, M.L., Bamman, D.J., 1994, Predicting FLDs with explicit and implicit FE codes, Proc. SAE Conference, Detroit, 481-495.
  • Hosford, W.F., 1979, On yield loci of anisotropic cubic metals, Proceedings 7th North American Metalworking Conference., SME, Dearborn MI, 191-197.
  • Hu, J.G., Jonas, J.J., Zhou, Y., Ishikawa, T., 1998, Influence of damage and texture evolution on limit strain in biaxially stretched aluminium alloy sheets, Materials Science Eng., A251,243-250.
  • Huang, H.M., Pan, J., Tang, S.C., 2000, Failure prediction in anisotropic sheet metals under forming operations with consideration of rotating principal stretch directions, Int. J. Plasticity, 16,611-633.
  • Inal, K, Neale, K.W., Aboutajeddine, A., 2005, Forming limit comparisons for FCC and BCC sheets, Int. J. Plasticity, 21, 1255-1266.
  • Jackson, K., Allwood, J., 2009, The mechanics of incremental sheet forming, J. Materials Process. Technol, 209, 1158-1174.
  • Janssens, K., Lambert, F., Vanrostenberghe, S., Vermeulen, M., 2001, Statistical evaluation of the uncertainty of experimentally characterized forming limits of sheet steel, J. Materials Process. Techn., 112, 174-184.
  • Jeswiet, J., Young, D., 2005, Forming limit diagrams for single-point incremental forming of aluminium sheet, Proc. IMech E: J. Eng. Manufact., Part B, 219, 1-6.
  • Jie, M., Cheng, C.H., Chan, L.C., Chow, C.L., 2009, Forming Limit Diagrams of strain-rate-dependent sheet metals, Int. Journal of Mechanical Science, 51, 269-275.
  • John Neil, C, Agnew, S.R., 2009, Crystal plasticity-based forming limit prediction for non-cubic metals: Application to Mg alloy AZ31B, Int. J. Plasticity, 25, 379-398.
  • Jurco, P., Banabic, D., 2005, A user-frienldy programme for calculating Forming Limit Diagrams, Proc. 8th ESAFORM Conference on Material Forming, ed., Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 423-427.
  • Karafillis, A.P., Boyce, M.C., 1993, A general anisotropic yield criterion using bounds and a transformation weighting tensor, J. Mech. Phys. Solids, 41, 1859-1886.
  • Karthik, V. et al., 2002, Variability of sheet formability and formability testing, J. Materials Process. Technol., 121, 350-362.
  • Keeler, S.P., 1961, Plastic instability and fracture in sheet stretched over rigid punches, PhD Thesis, Massachusetts Institute of Technology, Boston.
  • Keeler, S.P., Backofen, W.A., 1963, Plastic instability and fracture in sheets stretched over rigid punches, Trans. ASM, 56, 25-48.
  • Keeler, S.P., 1970, La formabilité est améliorée par pression hydrostatique, Machine Moderne, 43-45.
  • Kim, K.J., Kim, D., Choi, S.H., Chung, K., Shin, K.S., Barlat, F., Oh, K.H., Youn, J.R., 2003, Formability of AA5182/polypropilylene/AA5182 sandwich sheets, J. Materials Process. Technol, 139, 1-7.
  • Kim, D., Kim, K.J., Chung, K., Barlat, F., Hong, S.H., Lee, J.H., 2008, Formulation of Forming Limit Diagram for sandwich sheet with anisotropic strain-rate potential, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 337-342.
  • Kim, J., Kang, B.-S., Lee, J.K., 2009, Statistical evaluation of forming limit in hydroforming process using plastic instability combined with FORM, Int. J. Adv. Manuf. Technol, 42, 53-59.
  • Knockaert, R., Chastel, Y., Massoni, E., 2000, Forming limits prediction using rate-independent polycrystalline plasticity, Int. J. Plasticity, 16, 179-198.
  • Koistinen DP, Wang NM (eds) (1978), Mechanics of sheet metal forming, Plenum Press, New-York London.
  • Krauer J., Hora, P., Tong, L., 2008, Temperature dependent forming limit prediction for metastable stainless steels, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 235-240.
  • Kuroda M., Tvergaard V., 2000a, FLD for anisotropic metal sheets with different yield criteria, Int. J. Solids Struct., 37, 5037-5059.
  • Kuroda M., Tvergaard V., 2000b, Effect of strain path change on limits to ductility of anisotropic metal sheets, Int. J. Mech. Sciences, 42, 867-887.
  • Kuroda, M., 2005, Effects of texture on mechanical properties of aluminium alloys sheets and texture optimization strategy, Proc. of the NUMISHEET 2005 Conf, eds, Smith, L.M., Pourboghrat, F., Yoon, J.-W., Stoughton,T.B., 445-450.
  • Lademo, O.G., Berstad, T., Hopperstad, O.S., Pedersen, K.O., 2004,      A numerical tool for formability analysis of aluminium alloys, Steel Grips, 2, 427-437.
  • Lademo, O.G., Hopperstad, O.S., Berstad, T., Langseth, M., 2005,          Prediction of plastic instability in extruded aluminium alloys using shell analysis and a coupled model of elasto-plasticity and damage, J. Materials Process. Techn., 166, 247-255.
  • Lemaitre, J. (ed.), 2001, Continuous damage, Handbook of Materials Behavior Models, Academic Press, San Diego, CA, 411-793.
  • Marciniak, Z., 1965, Stability of plastic shells under tension with   kinematic   boundary   condition, Archiwum Mechaniki Stosowanej, 17, 577-592.
  • Marciniak, Z, Kuczynski, K., 1967, Limit strains in the process of stretch-forming sheet metal, Int. J. Mech. Sci., 9, 609-620.
  • Marciniak, Z., 1968, Analysis of necking preceding fracture of sheet metal under tension, La Metallurgia Italiana, 8, 701-709.
  • Matin, P.H., Smith, L.M., 2005, Practical limitations to the influence of through-thickness normal stress on sheet metal formability, International Journal of Plasticity, 21,671-690.
  • Mattiasson, K., Sigvant, M., Larsson, M., 2007, On the prediction of plastic instability in metal sheets, Proc. NUMLFORM'O7 Conference, eds, Cesar de Sa, J.M.A., Santos, A.D., 908, 129-135.
  • Mattiasson, K., Sigvant, M., Larsson, M., 2008, On the role of strain rate in finite element simulations of sheet forming processes, Proc. of the NUMISHEET 2008 Conf. (Part B. Benchmark study), ed., Hora, P., Interlaken, Switzerland, 223-228.
  • Mattiasson, K., Sigvant M., 2008, An evaluation of some recent yield criteria for industrial simulations of sheet forming processes, International Journal of Mechanical Sciences, 50, 774-787.
  • McGinty, R., McDowell, D.L., 2004, Application of multiscale crystal plasticity models to FLD, Trans.ASME., J. Eng. Mater. Techn., 126, 285-291.
  • Nakazima, K, Kikuma, T, Hasuka, K., 1971, Study on the formability of steel sheets, Yawata Tech. Rep., 284, 678-680.
  • Narashimhan, K., Nandedkar, V.M., 1996, Finite element modeling of in-plane forming limit strains under constant and changing strain paths, Proc. of the NUMISHEET 1996 Conference, eds, Lee, J.K., Kinzel, G.L., Wagoner, R.H., Dearborn, 280-285.
  • Nandedkar, V.M, Narashimhan, K., 1999, Prediction of forming limits incorporating work-hardening behavior, Proc. of the NUMISHEET 1999 Conference, eds, Gelin, J.C., Picart, P, Besancon, 437-442.
  • Narashimhan, K., Wagoner, R.H., 1991, Finite Element Modeling simulation of in-plane FLD of sheets containing finite defects, Metallurgical Trans., 22A, 2655-2665.
  • Paraianu, L., Banabic, D., 2005, Calculation of Forming Limit Diagrams Using a Finite Element Model, Proc. 8' ESAFORM Conference on Material Forming, ed., Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 419-423.
  • Paraianu, L., Comsa, D.S., Gracio, J.J., Banabic, D., 2006, Influence of yield locus and strain-rate sensitivity on the Forming Limit Diagrams, Proc. 9th ESAFORM Conference on Material Forming, eds, Juster, N., Rosochowski, A., Glasgow, The Publishing House AKAPIT, Krakow, 343-346.
  • Parsa, M.H., Ettehad, M., Nasher Al Ahkami, S., 2009, FLD determination of al 3105/polypropylene/Al 3105 sandwich sheet using numerical calculation and experimental investigations, Proc. of the 12th ESAFORM Conference on Material Forming, eds, van den Boogart, T., Akker-man, R., Enshede.
  • Petek, A., Kuzman, K., 2007, The determination of the FLD for conventional and single point incremental sheet metal forming, Proc. of the IDDRG 2007 Conference, ed., Tisza, M., Gyor, 249-256.
  • Rajarajan, G., Kleiner, M., Roesen, H., Kessler, L., 2005, Validation of the non-linear strain path model CRACH to enhance the interpretation of FE simulations in multistage forming operations, Proc. 8th ESAFORM Conference on Material Forming, ed., Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 387-390.
  • Ragab, A.R., Saleh, C, 2000, Effect of void growth on the predicting forming limit strains for planar isotropic sheet metals, Mechanics of Materials, 32, 71-84.
  • Ragab, A.R., Saleh, C, Zaafarani, N.N., 2002, Forming limit diagrams for kinematically hardened voided sheet metals,Materials Process. Techn., 128, 302-312.
  • Rechberger, F., Till, E.T., 2004, Influence of scatter of materials properties on the formability of parts, Forming the future, Proc. IDDRG 2004 Conference, ed., Kergen, R., Sindelfingen, 236-245.
  • Savoie, J., Jain, M., Carr, A.R., Wu, P.D., Neale, K.W., Zhou, Y., Jonas, J.J., 1998, Prediction of the FLD using crystal plasticity model, Materials Science Eng., A257, 128-133.
  • Shakeri, M., Sadough, A., Dariani, B.M., 2000, Effect of pre-straining and grain size on the limit strains in sheet metal forming, Proc. Instn. Mech. Engrs., 214B, 821-827.
  • Shim, M.S., Park, J.J., 2001, The formabiltiy of aluminium sheet in incremental forming, J. Mater. Process. Technol., 113, 654-658.
  • Signorelli, J.W., Bertinetti, M.A., Turner, P.A., 2009, Predictions of forming limit diagrams using a rate-dependent polycrystal self-consistent plasticity model, International Journal of Plasticity, 25, 1-25.
  • Signorelli, J.W., Bertinetti, M.A., 2009, On the role of constitutive model in the forming limit of FCC sheet metal with cube orientations, International Journal of Mechanical Sciences, 51,473-480.
  • Smith, L.M., Averill, R.C., Lucas, J.P., Stoughton, T.B., Matin, P.H., 2003, Influence of transverse normal stress on sheet metal formability, International Journal of Plasticity, 19, 1567-1583.
  • Soare, S, Yoon, J.W., Cazacu. O., 2007, On using homogeneous polynomials to design anisotropic yield functions with tension/compression symmetry/asymmetry, Materials Processing and Design: Modeling, Simulation and Applications. Proc. of the NUMIFORM 2007 Conf, eds, Cesar de Sa, J.M.A., Santos, A.D., Porto, 607-612.
  • Soare, S., Banabic, D., 2008, Application of a polynomial yield function to the predictions of limit strains, Steel Research International, 79, 39-46.
  • Soare, S., Banabic, D, 2009, A discussion upon the sensitivity of the MK model to input data, Int. Journal Material Forming, 2, 503-506.
  • Stören, S., Rice, J.R., 1975, Localized necking in thin sheets, J. Mech. Phys. Solids, 23, 421-441.
  • Stoughton, T.B., 2000, A general forming limit criterion for sheet metal forming, Int. J. Mech. Sci., 42, 1-27.
  • Strano, M., Colosimo, B.M., 2006a, Logistic regression analysis for experimental determination of forming limit diagrams, Int. J. Machine Tools Manuf 46, 673-682.
  • Strano, M., Colosimo, B.M., 2006b, Ordinal logistic regression analysis for statistical determination of forming limit diagrams, Proc. 9th ESAFORM Conference on Material Forming, eds, Juster, N., Rosochowski, A., Glasgow, The Publishing House AKAPIT, Krakow, 303-306.
  • Swift, H.W., 1952, Plastic instability under plane stress, J. Mech. Phys.Sol, 1, 1-16.
  • Tai, W.H., Lee, W.B., 1996, Finite element simulation of in plane forming processes of sheets containing plastic damage, Proc. of the NUMISHEET 1996 Conference, eds, Lee, J.K., Kinzel, G.L., Wagoner, R.H., Dearborn, 257-261.
  • Teixeira, P., Andrade Pires, F.M., Santos, A.D., Cesar de Sa, J., 2006, Finite element prediction of fracture onset in sheet metal forming using a ductile damage model, Proc. of the IDDRG 2006 Conference, Porto, 239-245.
  • Teodosiu, C, Hu, H., 1995, Microstructure in the continuum modeling of plastic anisotropy, Proc. of the Conference, NUMIFORM'95 on Simulation of Materials Processing, Theory, Methods and Applications, eds, Shen, S., Dawson, P.R., Balkema, Rotterdam, 173-178.
  • Van den Boogaard, A.H., Huetink, J., 2003, Prediction of sheet necking with shell finite element models, Proc. 6th ESAFORM Conference on Material Forming, ed., Brucato, V., Salerno, Nuova Ipsa Editore, Palermo, 191-194.
  • Van Houtte, P., Toth L.S., 1993, Generalization of the Marciniak-Kuczynski defect model for predicting FLD, Advances in Engineering Plasticity and its Application, ed., Lee, W.B., Elsevier, Amsterdam, 1013-1020.
  • Van Houtte, P., 1994, Application of plastic potentials to strain rate sensitive and insensitive anisotropic materials, Int. J. Plasticity, 10, 719-748.
  • Van Houtte, P., 2005, Anisotropy and formability in sheet metal drawing, Proc. 8lh ESAFORM Conference on Material Forming, ed., Banabic, D., Cluj-Napoca, The Publishing House of the Romanian Academy, Bucharest, 339-342.
  • Van Minh, H., Sowerby R., Duncan J.L., 1973, Variability of Forming Limit Curves, Int. J. Mech. Sci., 16, 31-44.
  • Vegter, H., An, Y., Pijlman, H.H., Huetink, J., 1999, Different approaches to describe the plastic material behaviour of steel and aluminium-alloys in sheet forming, Proc. of the 2nd ESAFORM Conference on Material Forming, ed., Covas, J.A., Guimaraes, 127-132.
  • Vegter, H., van den Boogaard, A.H., 2006, A plane stress yield function for anisotropic sheet material by interpolation of biaxial stress states, Int. J. Plasticity, 22, 557-580.
  • Vegter, H., ten Horn, C.H.L.J., Abspoel, M., 2008, Modeling of the Forming Limit Curve by MK Analysis and FE simulations, Proc. of the NUMISHEET 2008 Conf. (Part B. Benchmark study), ed., Hora, P., Interlaken, Switzerland, 187-192.
  • Viatkina, E.M., Brekelmans, W.A.M., Evers, L.P., 2001, Forming Limit Diagrams for sheet deformation process: a crystal plasticity approach, Proc. of the 4"d ESAFORM Conference on Material Forming, ed., Habraken, A.M., Liege, 465-468.
  • Vos, M., Banabic, D., 2007, The Forming Limit Band - a new tool for increasing the robustness in the simulation of sheet metal forming processes, Proc. of the IDDRG 2007 Conference, Gyor, 165-176.
  • Wagoner, R.H., Chan, K.S., Keeler, S.P. (eds), 1989, Forming Limit Diagrams: Concepts, Methods, and Applications, TMS, Warrendale.
  • Wu, P.D., Neale, K.W., Van der Giessen, E., 1997, On crystal plasticity FLD analysis, Proc. R. Soc. London, 453, 1831-1848.
  • Wu, P.D. et al., 1998, Crystal plasticity FLD analysis of rolled aluminium sheets, Metallurgical Trans., 29A, 527-535
  • Wu, P.D., MacEwen, S.R., Lloyd, D.J., Neale, K.W., 2004, A mesoscopic approach for predicting sheet metal formability, Model. Simul. Mater. Sci. Eng., 12, 511-527.
  • Wu, P.D., Graf, A., MacEwen, S.R., Lloyd, D.J., Jain, M., Neale, K.W., 2005, On forming limit stress diagram analysis, Int. J. Solids Struct., 42, 2225-2241.
  • Wu, P.D., Lloyd, D.J. Jain, M., Neale, K.W., Huang, Y., 2007, Effects of spatial grain orientation distribution and initial surface topography on sheet metal necking, International Journal of Plasticity, 23, 1084-1104.
  • Wu, P.D., Embury, J.D., Lloyd, D.J., Huang, Y., Neale, K.W., 2009, Effects of superimposed hydrostatic pressure on sheet metal formability, International Journal of Plasticity,25, 1711-1725.
  • Xu, Y., 2006, Modern Formability: Measurement, Analysis and Applications, Hanser Gardner Publications.
  • Yao, H., Cao, J., 2002, Prediction of FLC using an anisotropic yield function with pre-strain induced pre-stress, Int. J. Plasticity, 18, 1013-1038.
  • Zhang, C, Leotoing, L., Guines, D., Ragneau, E., 2008, Theoretical and numerical study of strain rate sensitivity on formability of sheet metal, Proc. of the NUMISHEET 2008 Conf, ed., Hora, P., Interlaken, Switzerland, 229-233.
  • Zhou. D., Wagoner, R.H., 1991, Use of arbitrary yield function in FE, Anisotropy and localization of plastic deformation, eds, Boehler, J.P., Khan, A.S., Elsevier, Amsterdam, 688-691.
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