Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process
Selective Electron Beam Melting (SEBM) is a representative powder bed fusion metal Additive Manufacturing (AM) technique that employs a high-energy electron beam for sintering and melting metal powder bed in a layer-wise fashion. High build temperatures (500 – 1100 oC) and vacuum fabrication environ...
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Nanyang Technological University
2020
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Engineering::Mechanical engineering::Prototyping Engineering::Materials::Mechanical strength of materials Chandra, Shubham Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
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Selective Electron Beam Melting (SEBM) is a representative powder bed fusion metal Additive Manufacturing (AM) technique that employs a high-energy electron beam for sintering and melting metal powder bed in a layer-wise fashion. High build temperatures (500 – 1100 oC) and vacuum fabrication environment are inherent to SEBM process, leading to residual stress- and contamination-free as-built parts. However, there is a lack of understanding in grain growth behaviour and control during microstructural evolution which eventually governs the mechanical properties of as-built parts. Additionally, the prevailing knowledge on hot cracking during AM of non-weldable Ni-based superalloys lacks a framework to relate the solidification parameters and microstructural features with crack susceptibility.
This study addresses the limitations in state-of-the-art research and utilizes multi-scale experimental and numerical simulation methods to investigate the grain growth behaviour and microstructural evolution with varying build geometries and metal powder sizes for three different engineering alloys, i.e. Ti-6Al-4V, Stainless Steel 316L (SS316L), and Ni-based Single Crystal (SX) superalloy. Furthermore, it also provides an analytical framework to correlate solidification parameters and microstructural features with the contingency of hot cracking in AM of Ni-based superalloys. In general, the key results of this thesis work can be clarified in the following sections:
First, a multi-scale numerical model is created based on SEBM processing of Ti-6Al-4V to investigate the grain growth behaviour and microstructural evolution with varying build geometries, e.g. V-, I-, and A-shaped parts. Model validation was carried out with the aid of a series of quantitative experimental observations on the as-built Ti-6Al-4V microstructure. It is found that the difference in Heat Affected Zone (HAZ) depths caused by varied beam scanning lengths resulted in the periodic microstructural banding in SEBM-built Ti-6Al-4V samples. Moreover, build geometry is determined to impact a dominant effect on solidification parameters, hence on the crystallographic texture of the as-built microstructure. The V-shaped part is identified to favour a strong <001> crystallographic texture with increasing build height in comparison to the A- and I-shaped counterparts.
Further insight into grain growth control is advanced by SEBM processing of austenitic stainless steel – SS316L. Effects of build geometry and powder size on crystallographic texture in the as-built parts are demonstrated by employing various and multi-scale characterization techniques. Thermal conductivities of the sintered powder bed and as-built samples were determined using the Laser Flash Apparatus (LFA). Optical Microscopy (OM), Field Emission Scanning Electron Microscopy (FESEM), and Back-Scattered Electron (BSE) imaging were utilized to investigate melt pool topology and single-phase dendritic microstructure. X-ray Diffraction (XRD) and Electron Back-Scattered Diffraction (EBSD) were utilized for bulk phase analysis and crystallographic texture measurements, respectively. Transmission Electron Microscopy (TEM) was employed to determine the deformation mechanisms in the as-built samples subjected to uniaxial tensile testing. It was observed that a fine columnar-dendritic microstructure with primarily <001> crystallographic texture could be achieved by varying the build geometry. Furthermore, the powder size distribution is found to have an important effect on the as-built crystallographic texture. Changing the powder size from fine to coarse led to a uniform equiaxed-grained microstructure with significant improvement in tensile strength and ductility by ~17% and ~62%, respectively.
Despite its advantages, SEBM processing of Ni-based SX superalloys is still challenging due to their hot cracking susceptibility during rapid solidification. Additionally, elevated build temperature facilitates the precipitation of unfavourable Topologically Close-Packed (TCP) phases. Examination of the as-built microstructure using OM, FESEM, and EBSD revealed severe hot cracking which was confined only to divergent Grain Boundaries (GBs). Investigation of TCP phases using Energy-Dispersive Spectroscopy (EDS) and Atom Probe Tomography (APT) confirmed them as Ta-rich C14 Laves phase. Finally, a generalized hot cracking criterion is presented in this study that can account for the mutual inclination of grains at a GB. This generalized criterion is a major advancement over state-of-the-art and can be used to quantitatively predict cracking susceptibility of a GB under any solidification conditions associated with AM processes universally. |
| author2 |
Tor Shu Beng |
| author_facet |
Tor Shu Beng Chandra, Shubham |
| format |
Thesis-Doctor of Philosophy |
| author |
Chandra, Shubham |
| author_sort |
Chandra, Shubham |
| title |
Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| title_short |
Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| title_full |
Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| title_fullStr |
Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| title_full_unstemmed |
Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| title_sort |
investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process |
| publisher |
Nanyang Technological University |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/143917 |
| _version_ |
1761781825562214400 |
| spelling |
sg-ntu-dr.10356-1439172023-03-11T18:03:43Z Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process Chandra, Shubham Tor Shu Beng School of Mechanical and Aerospace Engineering Singapore Centre for 3D Printing MSBTOR@ntu.edu.sg Engineering::Mechanical engineering::Prototyping Engineering::Materials::Mechanical strength of materials Selective Electron Beam Melting (SEBM) is a representative powder bed fusion metal Additive Manufacturing (AM) technique that employs a high-energy electron beam for sintering and melting metal powder bed in a layer-wise fashion. High build temperatures (500 – 1100 oC) and vacuum fabrication environment are inherent to SEBM process, leading to residual stress- and contamination-free as-built parts. However, there is a lack of understanding in grain growth behaviour and control during microstructural evolution which eventually governs the mechanical properties of as-built parts. Additionally, the prevailing knowledge on hot cracking during AM of non-weldable Ni-based superalloys lacks a framework to relate the solidification parameters and microstructural features with crack susceptibility. This study addresses the limitations in state-of-the-art research and utilizes multi-scale experimental and numerical simulation methods to investigate the grain growth behaviour and microstructural evolution with varying build geometries and metal powder sizes for three different engineering alloys, i.e. Ti-6Al-4V, Stainless Steel 316L (SS316L), and Ni-based Single Crystal (SX) superalloy. Furthermore, it also provides an analytical framework to correlate solidification parameters and microstructural features with the contingency of hot cracking in AM of Ni-based superalloys. In general, the key results of this thesis work can be clarified in the following sections: First, a multi-scale numerical model is created based on SEBM processing of Ti-6Al-4V to investigate the grain growth behaviour and microstructural evolution with varying build geometries, e.g. V-, I-, and A-shaped parts. Model validation was carried out with the aid of a series of quantitative experimental observations on the as-built Ti-6Al-4V microstructure. It is found that the difference in Heat Affected Zone (HAZ) depths caused by varied beam scanning lengths resulted in the periodic microstructural banding in SEBM-built Ti-6Al-4V samples. Moreover, build geometry is determined to impact a dominant effect on solidification parameters, hence on the crystallographic texture of the as-built microstructure. The V-shaped part is identified to favour a strong <001> crystallographic texture with increasing build height in comparison to the A- and I-shaped counterparts. Further insight into grain growth control is advanced by SEBM processing of austenitic stainless steel – SS316L. Effects of build geometry and powder size on crystallographic texture in the as-built parts are demonstrated by employing various and multi-scale characterization techniques. Thermal conductivities of the sintered powder bed and as-built samples were determined using the Laser Flash Apparatus (LFA). Optical Microscopy (OM), Field Emission Scanning Electron Microscopy (FESEM), and Back-Scattered Electron (BSE) imaging were utilized to investigate melt pool topology and single-phase dendritic microstructure. X-ray Diffraction (XRD) and Electron Back-Scattered Diffraction (EBSD) were utilized for bulk phase analysis and crystallographic texture measurements, respectively. Transmission Electron Microscopy (TEM) was employed to determine the deformation mechanisms in the as-built samples subjected to uniaxial tensile testing. It was observed that a fine columnar-dendritic microstructure with primarily <001> crystallographic texture could be achieved by varying the build geometry. Furthermore, the powder size distribution is found to have an important effect on the as-built crystallographic texture. Changing the powder size from fine to coarse led to a uniform equiaxed-grained microstructure with significant improvement in tensile strength and ductility by ~17% and ~62%, respectively. Despite its advantages, SEBM processing of Ni-based SX superalloys is still challenging due to their hot cracking susceptibility during rapid solidification. Additionally, elevated build temperature facilitates the precipitation of unfavourable Topologically Close-Packed (TCP) phases. Examination of the as-built microstructure using OM, FESEM, and EBSD revealed severe hot cracking which was confined only to divergent Grain Boundaries (GBs). Investigation of TCP phases using Energy-Dispersive Spectroscopy (EDS) and Atom Probe Tomography (APT) confirmed them as Ta-rich C14 Laves phase. Finally, a generalized hot cracking criterion is presented in this study that can account for the mutual inclination of grains at a GB. This generalized criterion is a major advancement over state-of-the-art and can be used to quantitatively predict cracking susceptibility of a GB under any solidification conditions associated with AM processes universally. Doctor of Philosophy 2020-10-01T03:01:11Z 2020-10-01T03:01:11Z 2020 Thesis-Doctor of Philosophy Chandra, S. (2020). Investigation of grain growth and microstructural evolution in electron beam melting additive manufacturing process. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/143917 10.32657/10356/143917 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |