Microstructural and Mechanical Aspects of AlSi7Mg0.6 Alloy Related to Scanning Strategies in L-PBF

Abstract AlSi7Mg0.6 alloy is the most widely used cast alloy for aerospace and automotive applications. Therefore, it is essential to explore the effect of scanning strategies parameters on the final part properties in the L-PBF process. The effect of stripes and chessboard strategies parameters such as stripes length, rotation angle, and chessboard island size on mechanical and microstructural properties of L-PBF processed AlSi7Mg0.6 alloy is studied. The evolution of the residual stresses is also investigated in the longitudinal and transverse directions. Cooling rates are also estimated using the cell size within the melt pool. Three distinct regions (i.e., fine, coarse, and heat affected zone) within the melt pool corresponding to different cooling rates could be identified based on Si morphology. The texture of the final material can be tailored by changing the scanning strategies. This study comprehensively presents the results concerning porosity, mechanical properties, crystallographic texture, cooling rates, grain morphology, and residual stresses for additively manufactured AlSi7Mg0.6 alloy.

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Compression Behaviour of Wire + Arc Additive Manufactured Structures

Metals ◽

10.3390/met11060877 ◽

2021 ◽

Vol 11 (6) ◽

pp. 877

Author(s):

Masoud Abbaszadeh ◽

Volker Ventzke ◽

Leonor Neto ◽

Stefan Riekehr ◽

Filomeno Martina ◽

...

Keyword(s):

Additive Manufacturing ◽

Large Scale ◽

Grain Morphology ◽

Electron Back Scatter Diffraction ◽

Compression Tests ◽

Homogeneous Microstructure ◽

Compression Loading ◽

Anisotropic Behaviour ◽

Mechanical And Microstructural Properties ◽

Wire Arc Additive Manufacturing

Increasing demand for producing large-scale metal components via additive manufacturing requires relatively high building rate processes, such as wire + arc additive manufacturing (WAAM). For the industrial implementation of this technology, a throughout understanding of material behaviour is needed. In the present work, structures of Ti-6Al-4V, AA2319 and S355JR steel fabricated by means of WAAM were investigated and compared with respect to their mechanical and microstructural properties, in particular under compression loading. The microstructure of WAAM specimens is assessed by scanning electron microscopy, electron back-scatter diffraction, and optical microscopy. In Ti-6Al-4V, the results show that the presence of the basal and prismatic crystal planes in normal direction lead to an anisotropic behaviour under compression. Although AA2319 shows initially an isotropic plastic behaviour, the directional porosity distribution leads to an anisotropic behaviour at final stages of the compression tests before failure. In S355JR steel, isotropic mechanical behaviour is observed due to the presence of a relatively homogeneous microstructure. Microhardness is related to grain morphology variations, where higher hardness near the inter-layer grain boundaries for Ti-6Al-4V and AA2319 as well as within the refined regions in S355JR steel is observed. In summary, this study analyzes and compares the behaviour of three different materials fabricated by WAAM under compression loading, an important loading condition in mechanical post-processing techniques of WAAM structures, such as rolling. In this regard, the data can also be utilized for future modelling activities in this direction.

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A Study on Laser Welding of Titanium and Stainless Steel

Volume 2: Materials; Joint MSEC-NAMRC-Manufacturing USA ◽

10.1115/msec2018-6584 ◽

2018 ◽

Author(s):

Angshuman Chattopadhyay ◽

Gopinath Muvvala ◽

Vikranth Racherla ◽

Ashish Kumar Nath

Keyword(s):

Stainless Steel ◽

Laser Welding ◽

Weld Joint ◽

Welding Speed ◽

Fusion Process ◽

Longitudinal Stress ◽

Transverse Cracks ◽

Cooling Rates ◽

Melt Pool ◽

Longitudinal Cracks

Joining of dissimilar metals and alloys has been envisioned since a long time with specific high end applications in various fields. One such combination is austenitic stainless steel grade SS304 and commercial grade titanium, which is very difficult to join under conventional fusion process due to extensive cracking and failure caused by mismatch in structural and thermal properties as well as formation of the extremely brittle and hard intermetallic compounds. One of the methods proposed in literature to control the formation of intermetallics is by fast cooling fusion process like laser beam welding. The present study has been done on laser welding of titanium and stainless steel AISI 304 to understand the interaction of these materials during laser welding at different laser power and welding speed which could yield different cooling rates. Two types of cracks were observed in the weld joint, namely longitudinal cracks and transverse cracks with respect to the weld direction. Longitudinal cracks could be completely eliminated at faster welding speeds, but transverse cracks were found little influenced by the welding speed. The thermal history, i.e. melt pool lifetime and cooling rate of the molten pool during laser welding was monitored and a relation between thermo-cycle with occurrence of cracks was established. It is inferred that the longitudinal cracks are mainly due to the formation of various brittle intermetallic phases of Fe and Ti, which could be minimized by providing relatively less melt pool lifetime at high welding speeds. The reason of the transverse cracks could be the generation of longitudinal stress in weld joint due to the large difference in the thermal expansion coefficient of steel and titanium. In order to mitigate the longitudinal stress laser welding was carried out with a novel experimental arrangement which ensured different cooling rates of these two metals during laser welding. With this the tendency of transverse cracks also could be minimized significantly.

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Evaluation of the impact of scanning strategies on residual stresses in selective laser melting

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-019-03396-9 ◽

2019 ◽

Vol 102 (5-8) ◽

pp. 2441-2450 ◽

Cited By ~ 19

Author(s):

L. Mugwagwa ◽

D. Dimitrov ◽

S. Matope ◽

I. Yadroitsev

Keyword(s):

Residual Stresses ◽

Selective Laser Melting ◽

Laser Melting ◽

Scanning Strategies ◽

The Impact

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Microstructure and Residual Stress Evolution of Laser Powder Bed Fused Inconel 718 under Heat Treatments

Journal of Materials Engineering and Performance ◽

10.1007/s11665-020-05338-z ◽

2020 ◽

Author(s):

Giulio Marchese ◽

Eleonora Atzeni ◽

Alessandro Salmi ◽

Sara Biamino

Keyword(s):

Residual Stresses ◽

Inconel 718 ◽

Heat Treatments ◽

Powder Bed Fusion ◽

Stress Evolution ◽

Laser Powder Bed Fusion ◽

Powder Bed ◽

Melt Pool ◽

Sintering Mechanisms ◽

Dendritic Structures

AbstractThe current work aimed to study the influence of various heat treatments on the microstructure, hardness, and residual stresses of Inconel 718 processed by laser powder bed fusion process. The reduction in residual stresses is crucial to avoid the deformation of the component during its removal from the building platform. Among the different heat treatments, 800 °C kept almost unaltered the original microstructure, reducing the residual stresses. Heat treatments at 900, 980, and 1065 °C gradually triggered the melt pool and dendritic structures dissolution, drastically reducing the residual stresses. Heat treatments at 900 and 980 °C involved the formation of δ phases, whereas 1065 °C generated carbides. These heat treatments were also performed on components with narrow internal channels revealing that heat treatments up to 900 °C did not trigger sintering mechanisms allowing to remove the powder from the inner channels.

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Separation of the Formation Mechanisms of Residual Stresses in LPBF 316L

Metals ◽

10.3390/met10091234 ◽

2020 ◽

Vol 10 (9) ◽

pp. 1234

Author(s):

Alexander Ulbricht ◽

Simon J. Altenburg ◽

Maximilian Sprengel ◽

Konstantin Sommer ◽

Gunther Mohr ◽

...

Keyword(s):

Residual Stress ◽

Stress Distribution ◽

Residual Stresses ◽

Residual Stress Distribution ◽

Formation Mechanisms ◽

Micro Computed Tomography ◽

Solidification Shrinkage ◽

Stainless Steel 316L ◽

Heat Accumulation ◽

Cooling Rates

Rapid cooling rates and steep temperature gradients are characteristic of additively manufactured parts and important factors for the residual stress formation. This study examined the influence of heat accumulation on the distribution of residual stress in two prisms produced by Laser Powder Bed Fusion (LPBF) of austenitic stainless steel 316L. The layers of the prisms were exposed using two different border fill scan strategies: one scanned from the centre to the perimeter and the other from the perimeter to the centre. The goal was to reveal the effect of different heat inputs on samples featuring the same solidification shrinkage. Residual stress was characterised in one plane perpendicular to the building direction at the mid height using Neutron and Lab X-ray diffraction. Thermography data obtained during the build process were analysed in order to correlate the cooling rates and apparent surface temperatures with the residual stress results. Optical microscopy and micro computed tomography were used to correlate defect populations with the residual stress distribution. The two scanning strategies led to residual stress distributions that were typical for additively manufactured components: compressive stresses in the bulk and tensile stresses at the surface. However, due to the different heat accumulation, the maximum residual stress levels differed. We concluded that solidification shrinkage plays a major role in determining the shape of the residual stress distribution, while the temperature gradient mechanism appears to determine the magnitude of peak residual stresses.

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Influence of Cooling Rates on the Dentrite Morphology and Hardness of the Surface-Chilled Mg-10Gd-3Y Magnesium Alloy

Materials Science Forum ◽

10.4028/www.scientific.net/msf.546-549.175 ◽

2007 ◽

Vol 546-549 ◽

pp. 175-178 ◽

Cited By ~ 1

Author(s):

Yang Zhou ◽

Li Ming Peng ◽

Qu Dong Wang ◽

Jin Bao Lin ◽

Wen Jiang Ding

Keyword(s):

Standard Deviation ◽

Magnesium Alloy ◽

Grain Boundary ◽

Cast Alloy ◽

The Other ◽

Hardness Distribution ◽

Cooling Rates

Mg-10wt%Gd-3wt%Y alloy was cast in a step-like mould, which provided five different cooling rates. The dentrite morphology and hardness of the as-cast alloy from the surface to the center was investigated and the influence of the cooling rates on these was analyzed. It was indicated that there were two different trends for the hardness distribution: in the section of the step castings with the two slowest cooling rates, the hardness decreased with the increase of depth; while in the other three step castings the hardness increased with the increase of depth. Also it was founded that the hardness could be influenced by the grain boundary, dentrite morphology and dentrite arm spacing (DAS) in the alloy. At last, according to the standard deviation curves of the hardness, the chilled depths were about 5mm in 1st step and 10mm in 2nd step. And the other steps were fully chilled.

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Comparison of microstructure, mechanical properties, and residual stresses in tungsten inert gas, laser, and electron beam welding of Ti–5Al–2.5Sn titanium alloy

Proceedings of the Institution of Mechanical Engineers Part L Journal of Materials Design and Applications ◽

10.1177/1464420717748345 ◽

2017 ◽

Vol 233 (7) ◽

pp. 1336-1351

Author(s):

Massab Junaid ◽

Khalid Rahman ◽

Fahd Nawaz Khan ◽

Nabi Bakhsh ◽

Mirza Nadeem Baig

Keyword(s):

Electron Beam ◽

Residual Stresses ◽

Power Density ◽

Fusion Zone ◽

High Power ◽

Electron Beam Welding ◽

Inert Gas ◽

High Power Density ◽

Cooling Rates ◽

Zone Width

Electron beam welding (EBW), pulsed Nd:YAG laser beam welding (P-LBW), and pulsed tungsten inert gas (P-TIG) welding of Ti–5Al–2.5Sn alloy were performed in order to prepare full penetration weldments. Owing to relatively high power density of EBW and LBW, the fusion zone width of EBW weldment was approximately equal to P-LBW weldment. The absence of shielding gas due to vacuum environment in EBW was beneficial to the joint quality (low oxide contents). However, less cooling rates were achieved compared to P-LBW as an increase in heat-affected zone width and partial α′ martensitic transformation in fusion zone were observed in EBW weldments. The microstructure in fusion zone in both the EBW and P-TIG weldments comprised of both acicular α and α′ martensite within the prior β grains. Hardness of the fusion zone in EBW was higher than the fusion zone of P-TIG but less than the fusion zone of P-LBW weldments due to the observed microstructural differences. Notch tensile specimen of P-LBW showed higher load capacity, ductility and absorbed energy as compared to P-TIG and EBW specimens due to the presence of high strength α′ martensite phase. Maximum sheet distortions and tensile residual stresses were observed in P-TIG weldments due to high overall heat input. The lowest residual stresses were found in P-LBW weldments, which were tensile in nature. This was owing to high power density and higher cooling rates in P-LBW operation. EBW weldment exhibited the highest compressive residual stresses due to which the service life of EBW weldment is expected to improve.

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Comparison of the EHLA and LPBF Process in Context of New Alloy Design Methods for LPBF

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1161.13 ◽

2021 ◽

Vol 1161 ◽

pp. 13-25

Author(s):

Stephan Koß ◽

Simon Ewald ◽

Marie-Noemi Bold ◽

Jan Hendrik Koch ◽

Maximilian Voshage ◽

...

Keyword(s):

Heat Conduction ◽

Chemical Composition ◽

Process Parameters ◽

Pool Size ◽

Alloy Development ◽

Cooling Rates ◽

Melt Pool ◽

Volume Energy ◽

Melt Pool Size ◽

Am Processes

Additive Manufacturing (AM) processes are becoming more and more important for production of parts with increasing geometrical complexity and functionality. However, to draw on the full potential of AM technologies, alloys that exploit process inherent particularities such as extremely high cooling rates (ca. 106 K/s) have to be developed. One of most important AM-processes is Laser Powder Bed Fusion (LPBF), a batch-wise process. This complicates experimental alloy development and increases the use of powder resources since only one chemical composition can be tested within one test job and the process chamber has to be cleaned carefully in between. The process Extreme High-Speed Laser Material Deposition (EHLA) has been found to have similar cooling rates as LPBF, however it uses an in situ supply of powders which allows an easy switching between materials and has potential for rapid alloy development methods. Since the mechanical properties of materials primarily depend on chemical composition and microstructure, which in turn depends heavily on the cooling rates in the production process, the EHLA-process could be used as a means for an accelerated alloy development for LPBF. However, to explore this possibility, a thorough comparison of the two processes has to be performed.In this work, EHLA and LPBF processes are compared and evaluated regarding the following characteristics: process parameters, laser intensities and volume energy densities, resulting microstructure (primary dendrite arm spacing, DAS), melt pool size and shape. The reference samples were manufactured using one set of LPBF process parameters and EHLA samples were manufactured using three different sets of process parameters.The volume energy densities Ev [J/mm³] of the processes were found to differ by a factor 2.4 with higher Ev observed in LPBF. However, considering that approximately 2 to 3 layers are remelted with each pass of the laser beam, the introduced Ev per pass approximates the Ev introduced in the EHLA process. The melt pool size as seen in a cross section in the EHLA-manufactured samples is approximately 25 times larger than in the LPBF-manufactured samples and its depth to width ratio (d/w ratio) can be attributed to a heat conduction welding process while the d/w ratio observed in the LPBF-manufactured sample suggests a transition process between heat conduction welding and deep welding. The observed DAS is in the same order of magnitude for both processes ranging from 0.55 to 1.15 µm in EHLA-manufactured samples and 0.73 µm in the LPBF-manufactured reference sample. Since the resulting microstructures of samples manufactured with both processes show this common feature and EHLA process parameters can be adjusted to control the cooling rates, the transferability between EHLA- and LPBF-processes is supported in this first investigation. Research for a more efficient alloy development for LPBF using EHLA will be continued by e.g. examining chemical compositions and performing mechanical testing.

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The Dimensional Accuracy of Thin-Walled Parts Manufactured by Laser-Powder Bed Fusion Process

Journal of Manufacturing and Materials Processing ◽

10.3390/jmmp4030091 ◽

2020 ◽

Vol 4 (3) ◽

pp. 91

Author(s):

Josef Tomas ◽

Leonhard Hitzler ◽

Marco Köller ◽

Jonas von Kobylinski ◽

Michael Sedlmajer ◽

...

Keyword(s):

Residual Stresses ◽

Dimensional Accuracy ◽

Powder Bed Fusion ◽

Laser Powder Bed Fusion ◽

Powder Bed ◽

Cooling Channels ◽

Thin Walled ◽

Scanning Strategies ◽

Different Diameters ◽

Functional Components

Laser-Powder Bed Fusion brings new possibilities for the design of parts, e.g., cutter shafts with integrated cooling channels close to the contour. However, there are new challenges to dimensional accuracy in the production of thin-walled components, e.g., heat exchangers. High degrees of dimensional accuracy are necessary for the production of functional components. The aim is to already achieve these during the process, to reduce post-processing costs and time. In this work, thin-walled ring specimens of H13 tool steel are produced and used for the analysis of dimensional accuracy and residual stresses. Two different scanning strategies were evaluated. One is a stripe scan strategy, which was automatically generated and provided by the machine manufacturer, and a (manually designed) sectional scan strategy. The ring segment strategy is designed by manually segmenting the geometry, which results in a longer preparation time. The samples were printed in different diameters and analyzed with respect to the degree of accuracy and residual stresses. The dimensional accuracy of ring specimens could be improved by up to 81% with the introduced sectional strategy compared to the standard approach.

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