Abstract
This research deals with the influences of material model on deformation which is induced by Wire Arc Additive Manufacturing (WAAM) process simulated by means of thermo-mechanical non-linear FEM method. The feedstock material model is based on stainless steel SS316L which stems from three different sources namely existing database, initial and deposited wire. The actual feedstock materials were analyzed using SEM–EDX and modelled using JMATPRO software. MSC Marc/Mentat is used as the numerical computation software to develop WAAM model and to carryout simulation analysis. The plasticity model of each material is taken based on the isotropic hardening rule with von-mises yield criteria. The strain rate is selected within the range of 0.01–1.0 s−1 and Goldak’s double ellipsoid is chosen as heat source model. Simplified rectangular bead shape as meshed model is developed to avoid the huge pre-processing effort as well as to reduce the computational time. The transient temperature distribution is performed as means of thermal analysis on all three simulation models prior to investigating the deformation result of the WAAM component. Based on the result of the simulation, the noticeable difference can be examined by the transient temperature distribution and substrate distortion. The substrate distortion analysis shows that the distortion pattern based on real SS316L filler wire has more distortion compared to WAAM with default library database of SS316L. By using material model based on database of SS316L, the substrate distortion and transient temperature distribution are lower compared to other models.
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References
Erhunmwun ID, Ikponmwosa UB (2017) Review on finite element method. J Appl Sci Environ Manage 21(5):999
Sun Y, He M, Sun P (2013) Numerical analysis of finite element method for a transient two-phase transport model of polymer electrolyte fuel cell. Proc Comput Sci 18:2167–2176
Gu J et al (2018) Deformation microstructures and strengthening mechanisms for the wire+arc additively manufactured Al-Mg4.5Mn alloy with inter-layer rolling. Mater Sci Eng 712:292–301
Rodrigues TA, Duarte V et al (2019) Current status and perspectives on wire and arc additive manufacturing (WAAM). Mater (Basel) 12(7)
Li JZ et al (2019) Review of wire arc additive manufacturing for 3D metal printing. Int J Autom Technol 13(3):346–353
J. Mehnen, J. Ding, H. Lockett, and P. Kazanas.: Design study for wire and arc additive manufacture. International Journal of Product Development, 19(1–3), 2–20, (2014)
Ding J, Colegrove P et al (2014) A computationally efficient finite element model of wire and arc additive manufacture. Int J Adv Manuf Technol 70(1–4):227–236
Denlinger ER, Michaleris P (2016) Effect of stress relaxation on distortion in additive manufacturing process modeling. Addit Manuf 12:51–59
Roman J, Colegrove P, Williams S (2018) Analytical model for distortion prediction in wire + arc additive manufacturing. Residual Stress 6:77–282
Graf M et al (2018) Numerical simulation of metallic wire arc additive manufacturing (WAAM). AIP Conf Proc 1960(1)
Turner R, Schroeder F, Ward RM, Brooks JW (2014) The importance of materials data and modelling parameters in an FE simulation of linear friction welding. Adv Mater Sci Eng:1–9
Lindgren LE (2001) Finite element modelling and simulation of welding part 2: improved material modeling. J Therm Stress 24(3):195–231
Pryl D, Cervenka J, Pukl R (2010) Material model for finite element modelling of fatigue crack growth in concrete. Proc Eng 2(1):203–212
Prajadhiana KP, Manurung YHP et al (2018) Fundamental analysis on substrate distortion induced by wire arc additive manufacturing using experiment and nonlinear FEM with simplified bead model. Int J Eng Technol 7(1)
Acknowledgements
The authors would like to express their gratitude to staff member of Smart Manufacturing Research Institute (SMRI) as well as staff of Welding Laboratory, Advanced Manufacturing Laboratory, Advanced Manufacturing Technology Excellence Centre (AMTEx) and Research Interest Group: Advanced Manufacturing Technology (RIG:AMT) at Faculty of Mechanical Engineering, Universiti Teknologi MARA (UiTM). This research is financially supported by DAAD Germany with Project Code: 57525437 (Future Technology Additive Manufacturing), Geran Inisiatif Penyeliaan (GIP) from Phase 1/2019 with Project Code: 600-IRMI 5/3/GIP (073/2020) and Fundamental Research Grant Scheme (FRGS)
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Prajadhiana, K.P., Manurung, Y.H.P., Adenan, M.S., Mat, M.F. (2021). Investigation of Material Model Effect on WAAM SS316L Using Numerical Simulation. In: Osman Zahid, M.N., Abdul Sani, A.S., Mohamad Yasin, M.R., Ismail, Z., Che Lah, N.A., Mohd Turan, F. (eds) Recent Trends in Manufacturing and Materials Towards Industry 4.0. Lecture Notes in Mechanical Engineering. Springer, Singapore. https://doi.org/10.1007/978-981-15-9505-9_32
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DOI: https://doi.org/10.1007/978-981-15-9505-9_32
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