Deformation-Induced Strengthening Mechanism in a Newly Designed L-40 Tool Steel Manufactured by Laser Powder Bed Fusion

doi:10.1007/s40195-022-01461-z

Abstract

Abstract:

The microstructural and mechanical properties of a newly designed tool steel (L-40), specifically designed to be employed in the laser powder bed fusion (LPBF) technique, were examined. Melt pool boundaries with submicron dendritic structures and about 14% retained austenite phase were evident after printing. The grain orientation after high cooling rate solidification is mostly < 110 > _α∥ building direction (BD). Then, the heat treatment converted the microstructure into a conventional martensitic phase, reduced the retained austenite to about 1.5%, and increased < 111 > _α∥BD texture. The heat-treated sample exhibits higher tensile strength (1720 ± 14 MPa) compared to the as-printed sample (1540 ± 26 MPa) along the building direction, mainly due to hardening caused by a lower volume fraction of retained austenite phase and precipitation of carbides. As a consequence of the strength-to-ductility trade-off, the heat-treated sample showed lower elongation (10% ± 2%) than that of the as-printed sample (18% ± 2%). It was observed that transformation-induced plasticity (TRIP) occurs in both the as-printed and heat-treated samples during tensile testing, which dynamically transforms the retained austenite into martensite, leading to improved ductility. The minimum driving force to initiate the displacive phase transformation is about 6000 J/mol, which was achieved during tensile testing. The strength and ductility of LPBF-produced L-40 were compared with the other LPBF-produced tool steels in literature; the data indicate that heat-treated L-40 has an excellent combination of strength and ductility complemented with high printability.

Key words: Additive manufacturing, Laser powder bed fusion, L-40 tool steel, Phase transformation

Yuan Tian, Kanwal Chadha, Clodualdo Aranas Jr.. Deformation-Induced Strengthening Mechanism in a Newly Designed L-40 Tool Steel Manufactured by Laser Powder Bed Fusion[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 21-34.

Figures/Tables 15

Table 1 Chemical composition of L-40 steel (in wt%)

C	Cr	Ni	Mo	Cu	Nb	N	Fe
0.15	11.2	2.01	1.77	0.75	0.05	0.059	Bal.

Fig. 1 a SEM image of the spherical L-40 powders, b powder size distribution of L-40 powders

Fig. 2 a Optical micrograph of the as-printed L-40 steel, b, c SEM images at different magnifications

Fig. 3 Electron backscatter diffraction analysis of as-printed L-40 steel sample: a IPF map, b phase analysis using EBSD and XRD, c grain boundary map

Fig. 4 Crystallographic texture of the as-printed sample showing the distribution of three different textures based on the building direction

Fig. 5 Optical micrographs with a low, b high magnifications and SEM images with c low, d high magnifications of heat-treated L-40 steel

Fig. 6 Electron backscatter diffraction analysis of heat-treated L-40 steel sample: a IPF map, b phase analysis using EBSD and XRD, c grain boundary map

Fig. 7 Crystallographic texture of the heat-treated sample showing the distribution of three different textures based on the building direction

Fig. 8 Engineering and true stress-strain curves associated with as-printed and heat-treated L-40 steel samples

Table 2 Mechanical properties of L-40 steel for both as-printed and heat-treated conditions

	Hardness (HRC)	Tensile strength (MPa)	Yield strength (MPa)	Elongation (%)	Toughness (J)
As-printed (BD)	46 ± 2	1540 ± 26	1150 ± 34	18 ± 2	46 ± 2
As-printed (TD)	46 ± 2	1490 ± 18	1200 ± 12	17 ± 2	38 ± 10
Heat-treated (BD)	50 ± 2	1720 ± 14	1420 ± 11	10 ± 2	10 ± 1
Heat-treated (TD)	50 ± 2	1720 ± 17	1420 ± 19	12 ± 2	8 ± 1

Fig. 9 Fractured surfaces after tensile testing of: a, b as-printed, and c, d heat-treated L-40 steel samples

Fig. 10 Fractured surfaces after Charpy impact tests of: a, b as-printed, and c, d heat-treated L-40 steel samples

Table 3 Comparison of the mechanical properties of L-40 with other tooling steels produced via LPBF

Type of alloy	Tensile strength (MPa)	Elongation (%)
MS1 maraging steel, aged [10]	2121 ± 8	8 ± 2
M789 steel, aged [20]	1784 ± 2	11 ± 1
FeCrMoVC tool steel, as-printed [14]	3796 ± 163	14.7 ± 2
H11 tool steel, tempered [12]	2148 ± 16	8.8 ± 1
Heatvar, aged [3]	1980 ± 20	2 ± 1
L-40, tempered (present work)	1720 ± 14	10 ± 2

Fig. 11 Electron backscatter diffraction (EBSD) analysis: a IPF and b phase maps of as-printed tensile-tested samples; c IPF and d phase maps of heat-treated sample

Fig. 12 The second derivative of the true stress-strain curves associated with: a as-printed and b heat-treated L-40 steel samples

References 40

[1]	N. Haghdadi, M. Laleh, M. Moyle, S. Primig, J. Mater. Sci. 56, 64 (2021) DOI URL
[2]	A. Armillotta, R. Baraggi, S. Fasoli, Int. J. Adv. Manuf. 71, 573 (2014) DOI URL
[3]	Y. Tian, K. Chadha, S.H. Kim, C. Aranas, Mater. Sci. Eng. A 805, 140801 (2021)
[4]	S.A.M. Tofail, E.P. Koumoulos, A. Bandyopadhyay, S. Bose, L. O’Donoghue, C. Charitidis, Mater. Today 21, 22 (2018)
[5]	P. Bajaj, A. Hariharan, A. Kini, P. Kurnsteiner, D. Raabe, E.A. Jagle, Mater. Sci. Eng. A 772, 138633 (2020)
[6]	P. Krakhmalev, I. Yadroitsava, G. Fredriksson, I. Yadroitsev, Mater. Des. 87, 380 (2015) DOI URL
[7]	C.Y. Yap, C.K. Chua, Z.L. Dong, Z.H. Liu, D.Q. Zhang, L.E. Loh, S.L. Sing, Appl. Phys. Rev. 2, 041101 (2015) DOI URL
[8]	J. Mutua, S. Nakata, T. Onda, Z.C. Chen, Mater. Des. 139, 486 (2018) DOI URL
[9]	C. Tan, K. Zhou, W. Ma, P. Zhang, M. Liu, T. Kuang, Mater. Des. 134, 23 (2017) DOI URL
[10]	S. Bodziak, K.S. Al-Rubaie, L.D. Valentina, F.H. Lafratta, E.C. Santos, A.M. Zanatta, Y. Chen, Mater. Charact. 151, 73 (2019) DOI URL
[11]	K. Chadha, Y. Tian, P. Bocher, J.G. Spray, C. Aranas Jr., Materials 13, 2380 (2020)
[12]	K. Kempen, B. Vrancken, S. Buls, L. Thijs, J. Van Humbeeck, J.P. Kruth, J. Manuf. Sci. Eng. 136, 061026 (2014) DOI URL
[13]	F. Huber, C. Bischof, O. Hentschel, J. Heberle, J. Zettl, K.Y. Nagulin, M. Schmidt, Mater. Sci. Eng. A 742, 109 (2019)
[14]	R. Casati, M. Coduri, N. Lecis, C. Andrianopoli, M. Vedani, Mater. Charact. 137, 50 (2018) DOI URL
[15]	O. Hentschel, C. Scheitler, A. Fedorov, D. Junker, A. Gorunov, A. Haimerl, M. Merklein, M. Schmidt, J. Laser Appl. 29, 022307 (2017) DOI URL
[16]	J. Sander, J. Hufenbach, L. Giebeler, H. Wendrock, U. Kuhn, J. Eckert, Mater. Des. 89, 335 (2016) DOI URL
[17]	J. Boes, A. Rottger, C. Mutke, C. Escher, W. Theisen, Addit. Manuf. 23, 170 (2018)
[18]	R. Mertens, B. Vrancken, N. Holmstock, Y. Kinds, J.P. Kruth, J. Van Humbeeck, Phys. Procedia 83, 882 (2016)
[19]	M. Narvan, K.S. Al-Rubaie, M. Elbestawi,Materials 12, 2284 (2019)
[20]	R. Palad, Y. Tian, K. Chadha, S. Rodrigues, C. Aranas, Mater. Lett. 275, 128026 (2020) DOI URL
[21]	U.K. Viswanathan, G.K. Dey, M.K. Asundi, Metall. Trans. A 24, 2429 (1993)
[22]	Formetrix Metals (acquired by MacLean-Fogg)(2018), .
[23]	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, Prog. Mater. Sci. 92, 112 (2018) DOI URL
[24]	C.P. Paul, P. Ganesh, S.K. Mishra, P. Bhargavaa, J. Nejib, A.K. Natha, Opt. Laser Technol. 39, 800 (2007) DOI URL
[25]	L. Thijs, M. Sistiaga, R. Wauthle, Q. Xie, J. Kruth, J. Humbeeckl, Acta Mater. 61, 4657 (2013) DOI URL
[26]	B. Fotovvati, S.F. Wayne, G. Lewis, E. Asadi, Adv. Mater. Sci. Eng. 2018, 4920718 (2018)
[27]	S.A. Khairallah, A.T. Anderson, A. Rubenchik, W.E. King, Acta Mater. 108, 36 (2016) DOI URL
[28]	Y. Tian, K. Chadha, C. Aranas, Mater. Sci. Eng. A 805, 140790 (2021)
[29]	Y. Zhao, W.T. Zhu, S. Yan, L.Q. Chen, Acta Metall. Sin-Engl. Lett. 32, 1237 (2019)
[30]	G. Azizi, H. Mirzadeh, M.H. Parsa, Acta Metall. Sin-Engl. Lett. 28, 1272 (2015)
[31]	H.C. Yu, Z.Z. Cai, G.Q. Fu, M.Y. Zhu, Acta Metall. Sin-Engl. Lett. 32, 352 (2019)
[32]	B. Sun, F. Fazeli, C. Scott, B. Guo, C. Aranas, X. Chu, M. Jahazi, S. Yue, Mater. Sci. Eng. A 729, 496 (2018)
[33]	E.I. Poliak, J.J. Jonas, Acta Mater. 44, 127 (1996) DOI URL
[34]	C. Ghosh, C. Aranas, J.J. Jonas, Prog. Mater. Sci. 82, 151 (2016) DOI URL
[35]	J.A. Lobo, G.H. Geiger, Metall. Trans. A 7, 1347 (1976)
[36]	S.M.C. Van Boheman, J. Sietsma, Mater. Sci. Eng. A 527, 6672 (2010)
[37]	C. Aranas, J.J. Jonas, Acta Mater. 82, 1 (2015) DOI URL
[38]	H. K.D.H. Bhadeshia, Handbook of Residual Stress and Deformation of Steel (ASM International, Materials Park, Ohio, 2002),pp.3-10
[39]	C. Aranas, S. Rodrigues, A. Fall, M. Jahazi, J.J. Jonas,Metals 8, 360 (2018)
[40]	C. Aranas, T. Nguyan-Minh, R. Grewal, J.J. Jonas, ISIJ Int. 55, 200 (2015) DOI URL