Microstructure and Size-Dependent Mechanical Properties of Additively Manufactured 316L Stainless Steels Produced by Laser Metal Deposition

doi:10.1007/s40195-022-01445-z

Abstract

Abstract:

Metal additive manufacturing (AM), as a disruptive technology in the field of fabricating metallic parts, has shown its ability to design component with macrostructural complexity. However, some of these functionally complex structures typically contain a wide range of feature sizes, namely, the characteristic length of elements in AM-produced components can vary from millimeter to meter-scale. The requisite for controlling performance covers nearly six orders of magnitude, from the microstructure to macro scale structure. Understanding the mechanical variation with the feature size is of critical importance for topology optimization engineers to make required design decisions. In this work, laser metal deposition (LMD) is adopted to manufacture 316L stainless steel (SS) samples. To evaluate the effect of defects and specimen size on mechanical properties of LMD-produced samples, five rectangular sample sizes which ranged from non-standard miniature size to ASTM standard sub-sized samples were machined from the block. Tensile test reveals that the mechanical properties including yield strength (YS), ultimate tensile strength (UTS), and elongation to failure (ε_f) are almost the identical for samples with ASTM standard size. Whilst, relatively lower YS and UTS values, except for ε_f, are observed for samples with a miniature size compared with that of ASTM standard samples. The ε_f values of LMD-produced 316L SS samples show a more complex trend with sample size, and are affected by three key influencing factors, namely, slimness ratio, cluster of pores, and occupancy location of lack of fusion defects. In general, the ε_f values exhibit a decreasing trend with the increase of slimness ratio. Microstructure characterization reveals that the LMD-produced 316L samples exhibited a high stress status at low angle grain boundaries, whilst its location changed to high angle grain boundaries after plastic deformation. The grain size refinement and austenite-to-martensite phase transformation occurred during plastic deformation might be responsible for the very high YS and UTS attained in this study. The experimental works carried out in this study is expected to provide a guideline for evaluating the mechanical properties of LMD-produced parts with complex structure, where critical parameter such as a certain slimness ratio has to be considered.

Key words: Additive manufacturing, Laser metal deposition, 316L stainless steel, Tensile properties, Slimness ratio

Hua-Zhen Jiang, Qi-Sheng Chen, Zheng-Yang Li, Xin-Ye Chen, Hui-Lei Sun, Shao-Ke Yao, Jia-Huiyu Fang, Qi-Yun Hu. Microstructure and Size-Dependent Mechanical Properties of Additively Manufactured 316L Stainless Steels Produced by Laser Metal Deposition[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 1-20.

Figures/Tables 19

Fig. 1 Experimental details in the study: a morphology of the as-used 316L SS powder, b a sketch of laser inside powder feeding nozzle, and c real photograph of the LMD system

Table 1 Chemical composition of as-used 316L SS powders (wt%)

Fe	Cr	Ni	Mo	Mn	Si	C	P	S
Bal.	19.30 ± 0.5	11.15 ± 0.65	1.70 ± 0.2	0.60 ± 0.3	1.40 ± 0.1	≤ 0.03	≤ 0.04	≤ 0.01

Table 2 Optimal process parameters used in this work

Laser power (W)	Beam diameter (mm)	Scanning speed (mm/s)	Powder feeding rate (g/min)	Hatch spacing (mm)	Layer thickness (mm)
1100	2.0	6.0	10.3	1.0	0.2

Fig. 2 a-e Detailed information about specimen geometries, f polished surface used for microstructural observation

Fig. 3 a Defects detection using OM method, b the corresponding distribution of defect size in terms of the major axis length in a, c OM image showing the columnar dendrites (e.g., region B) and cells (e.g., region A) in the material, the yellow and blue arrows indicate dendrites and cells, respectively, d SEM image revealing the solidification microstructure, e a magnified view showing the columnar dendrite and cell structures

Fig. 4 Microstructure of LMD-produced 316L SS sample observed by EBSD: a IQ map, b IPF image, c PF image, d band contrast map, e KAM map, f phase mapping, g misorientation angle distribution, and h grain size distribution

Fig. 5 A summary of mechanical properties versus specimen size for LMD-produced 316L SS samples: a yield strength, b ultimate tensile strength, c elongation to failure, and d slimness ratio dependence of elongation to failure with different specimen sizes

Fig. 6 Represented fracture surface of sample ‘S0.5-1’ (εf?=?12.9%). a Macroscopic fracture morphology, b, c are enlarged images showing the pore defects, d a high magnified image revealing the dimple fracture and oxide particles

Fig. 7 Represented fracture surface of sample ‘S1-1’ (εf?=?14.2%). a Macroscopic fracture morphology, b, c are enlarged images showing the pores and lack of fusion defects, d a high magnified image revealing the dimple fracture and oxide particles

Fig. 8 Represented fracture surface of sample ‘S2-2’ (εf?=?11.7%). a Macroscopic fracture morphology, b SEM image revealing the lack of fusion defects, c an enlarged image showing the pores, d a high magnified image revealing the dimple fracture and oxide particles

Fig. 9 Represented fracture surface of sample ‘w4.5-4’ (εf?=?12.2%). a Macroscopic fracture morphology, b, c enlarged images showing the dimple fracture and oxide particles

Fig. 10 Represented fracture surface of sample ‘w10-4’ (εf?=?15.7%). a Macroscopic fracture morphology, b SEM image revealing the pore defect, c a high magnified image revealing the dimple fracture and oxide particles

Fig. 11 Represented fracture surface of sample ‘w10-1’ (εf?=?35%). a Macroscopic fracture morphology, b, c are enlarged images showing the pores and lack of fusion defects, d a high magnified image revealing the dimple fracture and oxide particles

Fig. 12 Defect size distribution measured on the observed fracture surfaces. The corresponding area fraction of defect region is also presented. a Sample ‘S1-1’, b Sample ‘S2-2’, c Sample ‘S0.5-1’, d Sample ‘w10-1’, e Sample ‘w10-4’, f Sample ‘w4.5-4’

Fig. 13 OM and SEM images showing a representative side view of LMD-produced specimen after tensile testing: a OM image showing the crack propagates to the edge of fractured sample surface, b OM image showing the crack initiates from the pore, c SEM image showing an intergranular fracture mode

Table 3 EDS analysis results of oxide particles and LMD-produced 316L base from different sample fracture surfaces (wt%)

Spectrum location	Element
Spectrum location	Si	Cr	Mn	Fe	Ni	Mo
Oxide particles	10.80 ± 1.61	27.11 ± 4.39	5.59 ± 2.93	45.25 ± 4.68	7.50 ± 1.00	2.36 ± 1.66
316L base material	0.58 ± 0.37	20.68 ± 1.82	0.60 ± 0.32	64.53 ± 2.87	10.78 ± 2.19	2.48 ± 1.35

Fig. 14 A summary of yield strength versus elongation to failure for LMD-produced 316L SS from our work and previous studies [5,79,14,16,17,18,19]. The reported values are collected from different references where the LMD-produced samples are produced by different processing parameters and are tensile tested by various sample sizes and shapes

Fig. 15 Microstructures of deformed sample: a IQ map, b band contrast map, c IPF image, d KAM map, e grain size distribution, f misorientation angle distribution, g phase mapping

Fig. 16 A magnified image of deformed sample observed in another area: a IPF image, b band contrast map, c phase mapping, d KAM map

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