CUSTODIAN - Laser Research Project
Published November 29, 2019 | Version v1
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Handbook on metallurgical defects and their genesis

Authors/Creators

  • 1. Politecnico di Milano, Material Section at Department of Mechanical Engineering

Description

This dataset represents Deliverable D1.1 "Handbook on metallurgical defects and their genesis" published by PoliMi within Work Package 1 about Definition of thermal cycles to reduce defect formation in SLM/LBW.

© COPYRIGHT 2019 The CUSTODIAN Consortium. All rights reserved.

Abstract:

Deliverable D1.1 of the Custodian Project gathers information on the features and mechanisms of generation of metallurgical defects that could be found after Laser powder bed fusion and Laser beam welding. Data are mainly obtained from a literature survey on available open publications. The reference materials for the project activities are the CM247LC and IN713LC alloys for LPBF and the AISI 304L austenitic stainless steel for LBW.

Files

Deliverable D1.1_Handbook on metallurgical defects and their genesis.pdf

Files (5.5 MB)

Additional details

Funding

European Commission
CUSTODIAN - Customized photonic devices for defectless laser based manufacturing 825103

References

  • [1] R.C. Reed, C.M.F. Rae. Physical metallurgy of the Nickel-based superalloys. Physical Metallurgy (fifth edition), Ed. D.E. Laughlin and K. Hono, Elsevier Publ. (2015) 2215-2290
  • [2] T. DebRoy, H.L. Wei, J.S. Zuback, T. Mukherjee, J.W. Elmer, J.O. Milewski, A.M. Beese, A. Wilson-Heid, A. De, W. Zhang. Additive manufacturing of metallic components – Process, structure and properties. Progress in Materials Science 92 (2018) 112–224
  • [3] S. Kou. Welding Metallurgy, John Wiley & Sons Publ. (2002)
  • [4] ASM Handbook. Vol. 1, Properties and Selection: Irons, steels and high-performance alloys. ASM International Publ. (2005) online ed.
  • [5] H.-E. Huang, C.-H. Koo. Characteristics and Mechanical Properties of Polycrystalline CM247LC Superalloy Casting. Materials Transactions, Vol. 45, No. 2 (2004) 562-568
  • [6] M. B. Henderson, D. Arrell, R. Larsson, M. Heobel & G. Marchant. Nickel based superalloy welding practices for industrial gas turbine applications. Science and Technology of Welding and Joining, 9 (2004) 13-21
  • [7] G. Çam & M. Koçak. Progress in joining of advanced materials. International Materials Reviews, 43 (1998) 1-44
  • [8] L.N. Carter, M.M. Attallah, R.C. Reed. Laser Powder Bed Fabrication of Nickel-Base Superalloys: Influence of Parameters; Characterisation, Quantification and Mitigation of Cracking. 12th INternationl Symposium on Superalloys. Ed. E.S. Huron, R.C. Reed, M.C. Hardy, M.J. Mills, R.E. Montero, P.D. Portella, J. Telesman. TMS Publ. (2012) 577-586
  • [9] P. Jonšta, Z. Jonšta, J. Sojka, L. Čížek, A. Hernas. Nickel super alloy IN713LC – structural characteristics after heat treatment. Journal of Achievements in Materials and Manufacturing Engineering. 22 (2007) 7-14
  • [10] P. Jonšta, Z. Jonšta, J. Sojka, L. Čížek, A. Hernas. Structural characteristics of nickel super alloy IN713LC after heat treatment. Journal of Achievements in Materials and Manufacturing Engineering. 21 (2007) 29-32
  • [11] A.Chamanfar, M.Jahazi, A.Bonakdar, E.Morin, A.Firoozrai. Cracking in fusion zone and heat affected zone of electron beam wel- ded Inconel-713LC gas turbine blades. Materials Science & Engineering, A642 (2015) 230–240
  • [12] M.K. Keshavarz, S. Turenne, A. Bonakdar. Solidification behavior of inconel 713LC gas turbine blades during electron beam welding. Journal of Manufacturing Processes, 31 (2018) 232–239
  • [13] S. Zla, B. Smetana, M. Zaludova, J. Dobrovska, V. Vodarek, K. Konecna, V. Matejka, H. Francova. Determination of thermophysical properties of high temperature alloy IN713LC by thermal analysis. Journal of. Thermal Analysi and Calorimetry, 110 (2012):211–219
  • [14] L.N. Carter, C.Martin, P.J. Withers, M.M. Attallah. The influence of the laser scan strategy on grain structure and cracking behaviour in SLM powder-bed fabricated nickel superalloy. Journal of Alloys and Compounds 615 (2014) 338–347
  • [15] V.D. Divya, R. Muñoz-Moreno, O.M.D.M. Messé J.S. Barnard, S. Baker, T. Illston, H.J. Stone. Microstructure of selective laser melted CM247LC nickel-based superalloy and its evolution through heat treatment. Materials Characterization 114 (2016) 62–74
  • [16] H. Peng, Y. Shi, S. Gong, H. Guo, B. Chen. Microstructure, mechanical properties and cracking behaviour in a γʹ-precipitation strengthened nickel-base superalloy fabricated by electron beam melting. Materials and Design 159 (2018) 155–169
  • [17] E. Chauvet, C. Tassin, J.-J. Blandin, R. Dendievel, G. Martin. Producing Ni-base superalloys single crystal by selective electron beam melting. Scripta Materialia 152 (2018) 15–19
  • [18] E. Chauvet, P. Kontis, E.A. Jågle, B. Gault, D. Raabe, C. Tassin, J.-J. Blandin, R. Dendievel, B. Vayre, S. Abed, G. Martin. Hot cracking mechanism affecting a non-weldable Ni-based superalloy produced by selective electron Beam Melting. Acta Materialia 142 (2018) 82-94.
  • [19] W.J. Sames, K.A. Unocic, G.W. Helmreich, M.M. Kirka, F. Medina, R.R. Dehoff, S.S. Babu. Feasibility of in situ controlled heat treatment (ISHT) of Inconel 718 during electron beam melting additive manufacturing. Additive Manufacturing 13 (2017) 156–165
  • [20] V. Manvatkar, A. De, and T. DebRoy. Heat transfer and material flow during laser assisted multi-layer additive Manufacturing. Journal of Applied Physics, 116 (2014) 124905
  • [21] H.L. Wei, G.L. Knapp, T. Mukherjee, T. DebRoy. Three-dimensional grain growth during multi-layer printing of a nickel based alloy Inconel 718. Additive Manufacturing 25 (2019) 448–459
  • [22] Y. Yang, F. Van Keulen, C. Ayas. A computationally efficient thermal model for selective laser melting. Additive Manufacturing (2019) preprint, doi: 10.1016/j.addma.2019.100955
  • [23] Y. Du, X. You, F. Qiao, L. Guo, Z. Liu. A model for predicting the temperature field during selective laser melting. Results in Physics 12 (2019) 52–60
  • [24] Y. Li, D.[24] Y. Li, D. Gu. Thermal behavior during selective laser melting of commercially puretitanium powder: Numerical simulation and experimental study. Additive Manufacturing 1–4 (2014) 99–109Gu. Thermal behavior during selective laser melting of commercially puretitanium powder: Numerical simulation and experimental study. Additive Manufacturing 1–4 (2014) 99–109
  • [25] Y. Li, K. Zhou, P. Tan , S.B. Tor, C.K. Chua, K.F. Leong. Modeling temperature and residual stress fields in selective laser melting. International Journal of Mechanical Sciences 136 (2018) 24–35
  • [26] G.L. Knapp, N. Raghavan, A. Plotkowski, T. DebRoy. Experiments and simulations on solidification microstructure for Inconel 718 in powder bed fusion electron beam additive manufacturing. Additive Manufacturing 25 (2019) 511–521
  • [27] H. Peng, M. Ghasri-Khouzan, S. Gong, R. Attardo, P. Ostiguy, B. Aboud Gatrell, J. Budzinski, C. Tomonto, J. Neidig, M. Ravi Shankar, R. Billo, D.B. Go, D. Hoelzle. Fast prediction of thermal distortion in metal powder bed fusion additive manufacturing: Part 1, a thermal circuit network model. Additive Manufacturing 22 (2018) 852–868
  • [28] H. Peng,1, Morteza Ghasri-Khouzani, S. Gong, R. Attardo, P. Ostiguy, R.B. Rogge, B.A. Gatrell, J. Budzinski, C. Tomonto, J. Neidig, M. Ravi Shankar, R. Billo, D.B. Go, D. Hoelzleh. Fast prediction of thermal distortion in metal powder bed fusion additive manufacturing: Part 2, a quasi-static thermo-mechanical model. Additive Manufacturing 22 (2018) 869–882
  • [29] J. Lippold, D.J. Kotecki. Welding Metallurgy and Weldability of Stainless Steels. J. Wiley Publisher (2005) 141-229
  • [30] J.C. Lippold. Solidification Behavior and Cracking Susceptibility of Pulsed-Laser Welds in Austenitic Stainless Steels. Welding Research Supplement of Welding Journal, 6 (1994) 129s – 139s
  • [31] N. Siva Shanmugam, G. Buvanashekaran, K. Sankaranarayanasamy, K. Manonmani. Some studies on temperature profiles in AISI 304 stainless steel sheet during laser beam welding using FE simulation. International Journal of Advanced Manufacturing Technologies, 43 (2009) 78–94
  • [32] J. Sabbaghzadeh, M. Azizi, M.J. Torkamany. Numerical and experimental investigation of seam welding with a pulsed laser. Optics & Laser Technology 40 (2008) 289–296
  • [33] K.M. Hafez, S. Katayama. Fiber laser welding of AISI 304 stainless steel plates. Quarterly Journal of the Japan Welding Society, 1 (2009) 1-5
  • [34] P.W. Hochanadel, M.J. Cola, A.M. Kelly, P.A. Papin. Pulsed Laser Beam Welding of 304 to 304L Stainless Steel: Effects of Welding Parameters on Cracking and Phase Transformations. Los Alamos National Laboratory Public report LA-UR-01-6144, Proceedings of Joining of Advanced and Specialty Materials IV, Indianapolis, Indiana, ASM International Publisher (2001) pp. 16–21
  • [35] P. Hochanadel, T. Lienert, R. Martinez, J. Martinez, M. Johnson. Weld Solidification Cracking in 304 to 304L Stainless Steel. Los Alamos National Laboratory Public report LA-UR10-04375. In: Hot Cracking Phenomena in Welds III. T. Böllinghaus, J. Lippold, C. Cross. Editors, Springer Publisher (2011) 145-160
  • [36] Comparative study of pulsed Nd:YAG laser welding of AISI 304 and AISI 316 stainless steels. N. Kumar, M. Mukherje, A. Bandyopadhyay. Optics & LaserTechnology, 88 (2017) 24– 39