Effect of Process Parameters on Defects, Melt Pool Shape, Microstructure, and Tensile Behavior of 316L Stainless Steel Produced by Selective Laser Melting

doi:10.1007/s40195-020-01143-8

Abstract

Abstract:

Previous studies have revealed that laser power and energy density are significant factors affecting the quality of parts manufactured by selective laser melting (SLM). The normalized equivalent density E₀* and dimensionless laser power q*, which can be regarded as a progress on the understanding of the corresponding dimensional quantities, are adopted in this study to examine the defects, melt pool shape, and primary dendrite spacing of the SLM-manufactured 316L stainless steel, because it reflects the combined effect of process parameters and material features. It is found that the number of large defects decreases with increasing E₀* due to enough heat input during the SLM process, but it will show an increasing trend when excessive heat input (i.e., utilizing a high E₀*) is imported into the powder bed. The q* plays an important role in controlling maximum temperature rising in the SLM process, and in turn, it affects the number of large defects. A large q* value results in a low value of absolute frequency of large defects, whereas a maximum value of absolute frequency of large defects is achieved at a low q* even if E₀* is very high. The density of the built parts is greater at a higher q* when E₀* remains constant. Increasing the melt pool depth at relatively low value of E₀* enhances the relative density of the parts. A narrow, deep melt pool can be easily generated at a high q* when E₀* is sufficiently high, but it may increase melt pool instability and cause keyhole defects. It is revealed that a low E₀* can lead to a high cooling rate, which results in a refined primary dendrite spacing. Relatively low E₀* is emphasized in selecting the process parameters for the tensile test sample fabrication. It shows that excellent tensile properties, namely ultimate tensile strength, yield strength, and elongation to failure of 773 MPa, 584 MPa, and 46%, respectively, can be achieved at a relatively low E₀* without heat treatment.

Key words: Selective laser melting, Defects, Melt pool shape, Primary dendrite spacing, Mechanical properties, 316L stainless steel

Hua-Zhen Jiang, Zheng-Yang Li, Tao Feng, Peng-Yue Wu, Qi-Sheng Chen, Yun-Long Feng, Long-Fei Chen, Jing-Yu Hou, He-Jian Xu. Effect of Process Parameters on Defects, Melt Pool Shape, Microstructure, and Tensile Behavior of 316L Stainless Steel Produced by Selective Laser Melting[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(4): 495-510.

Figures/Tables 17

Table 1 List of processing parameters in this study

Sample No.	Process parameters						Volume energy density	Normalized equivalent energy density	Experimental results of relative density
Sample No.	q (W)	q*	v (mm/s)	v*	h (μm)	h*	E (J/mm³)	E₀*	ρ₀ (%)
Low power
1	95	20.99	415	3.09	50	1.25	152.61	4.21	97.70±0.97
2	95	20.99	415	3.09	70	1.75	109.01	3.00	96.78±1.03
3	95	20.99	415	3.09	90	2.25	84.78	2.34	97.71±1.09
4	95	20.99	415	3.09	110	2.75	69.37	1.91	98.49±0.32
5	95	20.99	415	3.09	130	3.25	58.70	1.62	97.69±0.43
6	95	20.99	650	4.83	90	2.25	54.13	1.49	98.14±0.62
7	95	20.99	530	3.94	90	2.25	66.39	1.83	97.97±0.58
8	95	20.99	300	2.23	90	2.25	117.28	3.23	97.72±0.84
9	95	20.99	185	1.38	90	2.25	190.19	5.24	95.95±0.80
Medium power
10	206	45.52	900	6.69	50	1.25	152.59	4.21	98.17±0.97
11	206	45.52	900	6.69	70	1.75	108.99	3.00	96.95±1.19
12	206	45.52	900	6.69	90	2.25	84.77	2.33	98.93±0.49
13	206	45.52	900	6.69	110	2.75	69.36	1.91	98.97±0.35
14	206	45.52	900	6.69	130	3.25	58.70	1.62	97.57±0.87
15	206	45.52	1400	10.41	90	2.25	54.50	1.50	98.66±0.43
16	206	45.52	1150	8.55	90	2.25	66.34	1.83	97.69±0.57
17	206	45.52	650	4.83	90	2.25	117.38	3.24	96.83±0.86
18	206	45.52	400	2.97	90	2.25	190.74	5.26	97.37±1.55
High power
19	360	79.54	1575	11.71	50	1.25	152.38	4.20	-
20	360	79.54	1575	11.71	70	1.75	108.84	3.00	-
21	360	79.54	1575	11.71	90	2.25	84.66	2.33	99.22±0.31
22	360	79.54	1575	11.71	110	2.75	69.26	1.91	98.14±0.88
23	360	79.54	1575	11.71	130	3.25	58.61	1.62	98.36±0.28
24	360	79.54	2465	18.33	90	2.25	54.09	1.49	98.60±0.23
25	360	79.54	2010	14.94	90	2.25	66.33	1.83	99.17±0.15
26	360	79.54	1135	8.44	90	2.25	117.47	3.24	98.50±0.40
27	360	79.54	700	5.20	90	2.25	190.48	5.25	97.96±0.83

Table 2 Thermophysical properties of 316L SS used for calculating the normalized quantities

A [22]	λ (W m^-1 K^-1) [23]	α (m² s^-1) [24]	ρ (kg m^-3) [25]	C_p (J kg^-1 K^-1) [23]	T_m (K) [10]		T₀ (K)
0.35	29.55	5.38×10^-6	7980	592.24	1673	333

Fig. 1 Normalized process map showing the location of dimensional variables corresponding to the experimental process parameters selected from Table 1 (the experimental data are enclosed in the blue dashed rectangle and the boundary of the experimental data in Ref. [16] is the black dashed rectangle). Contours of constant normalized equivalent energy density, E0*, are provided by the dashed lines

Fig. 2 SEM image of the 316L SS powder used

Fig. 3 Layout of cube array (the blue arrows indicate that the part cannot be successfully fabricated under this process parameter)

Fig. 4 Dimension of the as-fabricated sample and as-fabricated tensile specimen: a sketch of the 24 regions of interest for evaluating the density of each part, among which 8 regions of interest for quantitative statistics of defect size and morphology are indicated by the blue rectangle; b dimension of the dogbone sample after machining

Fig. 5 Effect of process parameters on relative density: a density measurement results, b a normalized processing diagram showing the location of high-density (>99%) SLM-processed part. The dashed lines represent contours of constant E0*

Fig. 6 SEM images showing the topography of the top surface structure of typical as-fabricated 316L SS samples: a-c effect of q* on the top surface structure when E0* is constant; c-e effect of E0* on the top surface structure when q* is constant; f magnified view of e

Fig. 7 Absolute frequency histograms illustrating the effect of process parameters on the size and morphology of defects: a-e defect size distributions f-j morphology distributions

Table 3 Absolute frequency of large defects and the total absolute frequency of defects detected at different samples

Sample	No. 9 (L-P, E₀*=5.25)	No. 18 (M-P, E₀*=5.25)	No. 27 (H-P, E₀*=5.25)	No. 21 (H-P, E₀*=2.33)	No. 24 (H-P, E₀*=1.49)
Absolute frequency of large defects (>50 μm)	161	60	32	15	46
Total absolute frequency of defects	3352	1430	3340	720	1265

Fig. 8 Nine OM images of cross-sectional views of scanning tracks with q* and E0* as abscissa and ordinate, respectively (the dark blue arrows indicate keyhole defects, while the green ones represent irregular defects)

Fig. 9 a Typical SEM image of the as-fabricated sample revealing the complex microstructure of 316L SS sample, b magnified view revealing the solidified cellular structures in a, c an example of conducting the SEM observations to measure the cell structure size at various process parameters

Fig. 10 Effect of process parameters on primary dendrite spacing (cell size)

Fig. 11 Effect of process parameters on the cooling rate of the as-fabricated samples

Fig. 12 Tensile properties of SLM-processed 316L SS: a engineering tensile stress-strain curves; b true stress-strain curves; c representative normalized work hardening rate curves as a function of true strain in the two process parameters

Fig. 13 SEM fractographs of the as-fabricated tensile specimens at different values of energy density: a-c Sample No. 24 (q*=79.54 and E0*=1.49) with unmelted spherical powder granules marked by blue arrows; d-f Sample No. 12 (q*=45.52 and E0*=2.33)

Fig. 14 Summary of ultimate tensile strength versus elongation to failure for 316L SS from our work and previous studies (the mechanical performance range of conventional wrought 316L SS is shown in the block region; HFA—hot finished+annealed; CFA—cold finished+annealed; CF—cold finished)

References 52

[1]	I. Yadroitsev, Dissertation (Central University of Technology, Free State, 2009)
[2]	C. Yu, Y. Zhong, P. Zhang, Z. Zhang, C. Zhao, Z. Zhang, Z. Shen, W. Liu, Acta Metall. Sin. Engl. Lett. 33 539 (2020)
[3]	Y. Zhong, L.F. Liu, S. Wikman, D.Q. Cui, Z.J. Shen, J. Nucl. Mater. 470 170 (2016)
[4]	C. Qiu, M. Al Kindi, A.S. Aladawi, I. Al Hatmi, Sci. Rep. 8 7785 (2018) URL PMID
[5]	L.Z. Wang, W.H. Wei, Acta Metall. Sin. Engl. Lett. 31 807 (2018)
[6]	J.H. Martin, B.D. Yahata, J.M. Hundley, J.A. Mayer, T.A. Schaedler, T.M. Pollock, Nature 549, 365 (2017) DOI URL PMID
[7]	D. Zhang, D. Qiu, M.A. Gibson, Y. Zheng, H.L. Fraser, D.H. StJohn, M.A. Easton, Nature 576, 91 (2019) URL PMID
[8]	M. Shamsujjoha, S.R. Agnew, J.M. Fitz-Gerald, W.R. Moore, T.A. Newman, Metall. Mater. Trans. A 49 3011 (2018)
[9]	Z.J. Sun, X.P. Tan, S.B. Tor, C.K. Chua, NPG. Asia Mater. 10 127 (2018)
[10]	Y.M. Wang, T. Voisin, J.T. McKeown, J. Ye, N.P. Calta, Z. Li, Z. Zeng, Y. Zhang, W. Chen, T.T. Roehling, R.T. Ott, M.K. Santala, P.J. Depond, M.J. Matthews, A.V. Hamza, T. Zhu, Nat. Mater. 17 63 (2018) URL PMID
[11]	L. Liu, Q. Ding, Y. Zhong, J. Zou, J. Wu, Y.L. Chiu, J. Li, Z. Zhang, Q. Yu, Z. Shen, Mater. Today 21 354 (2018) DOI URL
[12]	W. Yang, Y. Tarng, J. Mater. Process. Technol. 84 122 (1998)
[13]	T. Mukherjee, V. Manvatkar, A. De, T. DebRoy, J. Appl. Phys. 121 064904 (2017)
[14]	J.C. Ion, H.R. Shercliff, M.F. Ashby, Acta Metall. Mater. 40 1539 (1992)
[15]	M. Thomas, G.J. Baxter, I. Todd, Acta Mater. 108 26 (2016)
[16]	H.Z. Jiang, Z.Y. Li, T. Feng, P.Y. Wu, Q.S. Chen, Y.L. Fen, S.W. Li, H. Gao, H.J. Xu, Opt. Laser. Technol. 119 105592 (2019)
[17]	K. Darvish, Z.W. Chen, T. Pasang, Mater. Des. 112 357 (2016)
[18]	Z. Li, T. Voisin, J.T. McKeown, J.C. Ye, T. Braun, C. Kamath, W.E. King, Y.M. Wang, Int. J. Plast. 120 395 (2019) DOI URL
[19]	H. Hou, E. Simsek, T. Ma, N.S. Johnson, S. Qian, C. Cissé, D. Stasak, N. Al Hasan, L. Zhou, Y. Hwang, Science 366, 1116 (2019) DOI URL PMID
[20]	E.O. Olakanmi, R.F. Cochrane, K.W. Dalgarno, J. Mater. Process. Technol. 211 113 (2011) DOI URL
[21]	M. Ma, Z. Wang, X. Zeng, Mater. Sci. Eng. A 685 265 (2017)
[22]	S.A. Khairallah, A.T. Anderson, A. Rubenchik, W.E. King, Acta Mater. 108 36 (2016)
[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)
[24]	W.E. King, H.D. Barth, V.M. Castillo, G.F. Gallegos, J.W. Gibbs, D.E. Hahn, C. Kamath, A.M. Rubenchik, J. Mater. Process. Technol. 214 2915 (2014)
[25]	C. Kamath, B. El-dasher, G.F. Gallegos, W.E. King, A. Sisto, Int. J. Adv. Manuf. Technol. 74 65 (2014)
[26]	A.B. Spierings, M. Schneider, R. Eggenberger, Rapid Prototyp. J. 17 380 (2011)
[27]	Z.J. Sun, X.P. Tan, S.B. Tor, W.Y. Yeong, Mater. Des. 104 197 (2016)
[28]	L. Thijs, F. Verhaeghe, T. Craeghs, J.V. Humbeeck, J.P. Kruth, Acta Mater. 58 3303 (2010) DOI URL PMID
[29]	J. Suryawanshi, K.G. Prashanth, U. Ramamurty, Mater. Sci. Eng. A 696 113 (2017)
[30]	C.L. Qiu, N.J.E. Adkins, M.M. Attallah, Acta Mater. 103 382 (2016) DOI URL
[31]	Y.M. Wang, C. Kamath, T. Voisin, Z. Li, Rapid. Prototyp. J. 24 1469 (2018)
[32]	C.L. Qiu, C. Panwisawas, M. Ward, H.C. Basoalto, J.W. Brooks, M.M. Attallah, Acta Mater. 96 72 (2015) DOI URL
[33]	J.A. Cherry, H.M. Davies, S. Mehmood, N.P. Lavery, S.G.R. Brown, J. Sienz, J. Sienz, Int. J. Adv. Manuf. Technol. 76 869 (2015)
[34]	T. Niendorf, S. Leuders, A. Riemer, H.A. Richard, T. Tröster, D. Schwarze, Metall. Mater. Trans. B 44 794 (2013)
[35]	R. Cunningham, C. Zhao, N. Parab, C. Kantzos, J. Pauza, K. Fezzaa, T. Sun, A.D. Rollett, Science 363, 849 (2019) DOI URL PMID
[36]	L. Cla, S. Marussi, R.C. Atwood, M. Towrie, P.J. Withers, P.D. Lee, Nat. Commun. 9 1355 (2018) URL PMID
[37]	T. Mukherjee, J.S. Zuback, A. De, T. DebRoy, Sci. Rep. 6 19717 (2016) DOI URL PMID
[38]	I. Yadroitsev, P. Bertrand, I. Smurov, Appl. Surf. Sci. 253 8064 (2007)
[39]	D. Wang, C.H. Song, Y.Q. Yang, Y.C. Bai, Mater. Des. 100 291 (2016)
[40]	M. Ma, Z. Wang, G. Ming, X. Zeng, J. Mater. Process. Technol. 215 142 (2015)
[41]	S. Katayama, A. Matsunawa, in International Congress on Applications of Lasers & Electro-Optics, vol. 44(Laser Institute of America, New York, 1984), p. 60
[42]	K. Saeidi, X. Gao, F. Lofaj, L. Kvetková, Z.J. Shen, J. Alloys Compd. 633 463 (2015) DOI URL
[43]	A.T. Sidambe, Y. Tian, P.B. Prangnell, P. Fox, Int. J. Refract. Met. Hard Mat. 78 254 (2019) DOI URL
[44]	D. Bäuerle, Laser Processing and Chemistry, 4th edn. (Springer, Berlin, 2011) URL PMID
[45]	R. Casati, J. Lemke, M. Vedani, J. Mater. Sci. Technol. 32 738 (2016)
[46]	K. Saeidi, L. Kvetkova, F. Lofajc, Z.J. Shen, RSC Adv. 5 20747 (2015)
[47]	C. Elangeswaran, A. Cutolo, G.K. Muralidharan, C. de Formanoir, F. Berto, K. Vanmeensel, B. Van Hooreweder, Int. J. Fatigue. 123 31 (2019)
[48]	A. Riemer, S. Leuders, M. Thöne, H. Richard, T. Tröster, T. Niendorf, Eng. Fract. Mech. 120 15 (2014)
[49]	T. Kurzynowski, K. Gruber, W. Stopyra, B. Kuźnicka, E. Chlebus, Mater. Sci. Eng. A. 718 64 (2018) DOI URL
[50]	ASM International Handbook Committee, ed. by S.D. Washko and G. Aggen. Properties and Selection: Irons, Steels, and High-Performance Alloys, vol. 1, 10th Edition (USA, 1990), p. 2049
[51]	K. Saeidi, X. Gao, Y. Zhong, Z.J. Shen, Mater. Sci. Eng. A 625 221 (2015)
[52]	T. Voisin, N.P. Calta, S.A. Khairallah, J.B. Forien, L. Balogh, R.W. Cunningham, A.D. Rollett, Y.M. Wang, Mater. Des. 158 113 (2018)