Your search keyword '"Narendran Raghavan"' showing total 13 results

1. Fluid Dynamics Effects on Microstructure Prediction in Single-Laser Tracks for Additive Manufacturing of IN625

Author

Vipul K. Gupta, Matthew T. Bement, Narendran Raghavan, Lang Yuan, Srdjan Simunovic, John A. Turner, and Adrian S. Sabau

Subjects

0209 industrial biotechnology, Materials science, 0211 other engineering and technologies, Metals and Alloys, Thermodynamics, Laminar flow, 02 engineering and technology, Condensed Matter Physics, Power law, Surface tension, Dendrite (crystal), Temperature gradient, 020901 industrial engineering & automation, Mechanics of Materials, Free surface, Heat transfer, Materials Chemistry, Fluid dynamics, 021102 mining & metallurgy

Abstract

Single-track laser fusion were simulated using a heat-transfer-solidification-only (HTS) model and its extension with fluid dynamics (HTS_FD) model using a parallel open-source code, which included laminar fluid dynamics, flat-free surface of the molten alloy, heat transfer, phase-change, evaporation, and surface tension phenomena. The results illustrate that the fluid dynamics affects the solidification and ensuing microstructure. For the HTS_FD simulations, thermal gradient, G was found to exhibit a maximum at the extremity of the solidified pool (i.e., at the free surface), while for HTS simulations, G exhibited a maximum around the entire edge of the solidified pool. HTS_FD simulations predicted a wider range of cooling rates than the HTS simulations, exhibited an increased spread in the solidification speed, V variation within the melt-pool with respect to the HTS model results. Primary dendrite arm spacing (PDAS) were evaluated based on power law correlations and marginal stability theory models using the (G, V) from HTS and HTS_FD simulations to quantify the effect of the fluid dynamics on the microstructure. At low-laser powers and low-scan speeds, the PDAS obtained with the fluid dynamics model (HTS_FD) was larger by more than 30 pct with respect to the PDAS calculated with the simple HTS model. A new PDAS correlation, i.e., $$ \lambda_{1} \left[ {\mu {\text{m}}} \right] = 832\;G\left[ {\text{K/m}} \right]^{ - 0.5} V\left[ {\text{m/s}} \right]^{ - 0.25} $$ λ 1 μ m = 832 G K/m - 0.5 V m/s - 0.25 , which uses the (G, V) results from the HTS_FD model was developed and validated against experimental results.

Published

2020

2. Experiments and simulations on solidification microstructure for Inconel 718 in powder bed fusion electron beam additive manufacturing

Author

Tarasankar Debroy, Narendran Raghavan, G.L. Knapp, and Alex Plotkowski

Subjects

Equiaxed crystals, 0209 industrial biotechnology, Materials science, Electron-beam additive manufacturing, Convective heat transfer, Biomedical Engineering, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Microstructure, Thermal conduction, Industrial and Manufacturing Engineering, 020901 industrial engineering & automation, Heat transfer, Fluid dynamics, General Materials Science, 0210 nano-technology, Inconel, Engineering (miscellaneous)

Abstract

Previous research on the powder bed fusion electron beam additive manufacturing of Inconel 718 has established a definite correlation between the processing conditions and the solidification microstructure of components. However, the direct role of physical phenomena such as fluid flow and vaporization on determining the solidification morphology have not been investigated quantitatively. Here we investigate the transient and spatial evolution of the fusion zone geometry, temperature gradients, and solidification growth rates during pulsed electron beam melting of the powder bed with a focus on the role of key physical phenomena. The effect of spot density during pulsing, which relates to the amount of heating of the build area during processing, on the columnar-to-equiaxed transition of the solidification structure was studied both experimentally and theoretically. Predictions and the evaluation of the role of heat transfer and fluid flow were established using existing solidification theories combined with transient, three-dimensional numerical heat transfer and fluid flow modeling. Metallurgical characteristics of the alloy’s solidification are extracted from the transient temperature fields, and microstructure is predicted and validated using optical images and electron backscattered diffraction data from the experimental results. Simulations show that the pure liquid region solidified quickly, creating a large two-phase, mushy region that exists during the majority of solidification. While conductive heat transfer dominates in the mushy region, both the pool geometry and the solidification parameters are affected by convective heat transfer. Finally, increased spot density during processing is shown to increase the time of solidification, lowering temperature gradients and increasing the probability of equiaxed grain formation.

Published

2019

3. 3D Characterization of the Columnar-to-Equiaxed Transition in Additively Manufactured Inconel 718

Author

Andrew T. Polonsky, McLean P. Echlin, Tresa M. Pollock, Ryan R. Dehoff, Michael M. Kirka, and Narendran Raghavan

Subjects

Flexibility (engineering), Equiaxed crystals, Materials science, Marangoni effect, law, Process (computing), Mechanical engineering, Welding, Inconel, Microstructure, law.invention, Characterization (materials science)

Abstract

Additive manufacturing (AM) provides enormous processing flexibility, enabling novel part geometries and optimized designs. Access to a local heat source further permits the potential for local microstructure control on the scale of individual melt pools, which can enable local control of part properties. In order to design tailored processing strategies for target microstructures, models predicting the columnar-to-equiaxed transition must be extended to the high solidification velocities and complex thermal histories present in AM. Here, we combine 3D characterization with advanced modeling techniques to develop a more complete understanding of the solidification process and evolution of microstructure during electron beam melting (EBM) of Inconel 718. Full calibration of existing microstructure prediction models demonstrates the differences between AM processes and more conventional welding techniques, underlying the need for accurate determination of key parameters that can only be measured directly in 3D. The ability to combine multisensor data in a consistent 3D framework via data fusion algorithms is essential to fully leverage these advanced characterization approaches. Thermal modeling provides insight on microstructure development within isolated solidification events and demonstrates the role of Marangoni effects on controlling solidification behavior.

Published

2020

4. Role of scan strategies on thermal gradient and solidification rate in electron beam powder bed fusion

Author

Ryan R. Dehoff, Narendran Raghavan, Michael M. Kirka, John A. Turner, Yousub Lee, Ralph B. Dinwiddie, and S. Suresh Babu

Subjects

0209 industrial biotechnology, Fusion, Materials science, business.industry, Biomedical Engineering, 02 engineering and technology, computer.file_format, 021001 nanoscience & nanotechnology, Frame rate, Industrial and Manufacturing Engineering, Temperature gradient, 020901 industrial engineering & automation, Optics, Heat transfer, Cathode ray, Trailing edge, General Materials Science, Boundary value problem, Raster graphics, 0210 nano-technology, business, Engineering (miscellaneous), computer

Abstract

Local microstructure control in electron beam powder bed fusion (EB-PBF) is of great interest to the additive manufacturing community to realize complex part geometry with targeted performance. The local microstructure control relies on having a detailed understanding of local melt pool physics (e.g., 3-D melt pool shape as well as spatial and temporal variations of thermal gradient (G) and solidification rate (R)). In this research, a new scan strategy referred to as ghost beam is numerically evaluated as a candidate to achieve the targeted G and R of IN718 alloy. The boundary conditions for simulations, including the speed (490 mm/s) and spatial locations of the beam within a given layer, are obtained by using series of snapshot images, recorded at 12,000 frames per second, using a high-speed camera. The heat transfer simulations were performed using TRUCHAS an open-source software deployed within a high-performance computational infrastructure. The simulation results showed that reheating at short beam on-time and time delay decreases both G and R. Local variation of R at the center of the melt pool trailing edge showed periodic temporal fluctuations. Finally, the ghost beam scan strategy was compared to other existing raster and spot scan strategies.

Published

2018

5. Additive Manufacturing of Nickel Superalloys: Opportunities for Innovation and Challenges Related to Qualification

Author

Ryan R. Dehoff, Narendran Raghavan, Curtis Lee Frederick, Alex Plotkowski, Yousub Lee, Michael Haines, Ralph B. Dinwiddie, S. Suresh Babu, S. J. Foster, J. Raplee, and M. K. Kirka

Subjects

010302 applied physics, Manufacturing technology, Service (systems architecture), Materials science, business.industry, Process (engineering), Big data, Metallurgy, Metals and Alloys, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Manufacturing engineering, Superalloy, Nickel, chemistry, Mechanics of Materials, Software deployment, 0103 physical sciences, Selective laser melting, 0210 nano-technology, business

Abstract

Innovative designs for turbines can be achieved by advances in nickel-based superalloys and manufacturing methods, including the adoption of additive manufacturing. In this regard, selective electron beam melting (SEBM) and selective laser melting (SLM) of nickel-based superalloys do provide distinct advantages. Furthermore, the direct energy deposition (DED) processes can be used for repair and reclamation of nickel alloy components. The current paper explores opportunities for innovation and qualification challenges with respect to deployment of AM as a disruptive manufacturing technology. In the first part of the paper, fundamental correlations of processing parameters to defect tendency and microstructure evolution will be explored using DED process. In the second part of the paper, opportunities for innovation in terms of site-specific control of microstructure during processing will be discussed. In the third part of the paper, challenges in qualification of AM parts for service will be discussed and potential methods to alleviate these issues through in situ process monitoring, and big data analytics are proposed.

Published

2018

6. Localized melt-scan strategy for site specific control of grain size and primary dendrite arm spacing in electron beam additive manufacturing

Author

John A. Turner, Alex Plotkowski, Suresh Babu, Narendran Raghavan, Srdjan Simunovic, Ryan R. Dehoff, and Michael M. Kirka

Subjects

010302 applied physics, Materials science, Electron-beam additive manufacturing, Polymers and Plastics, Metallurgy, Metals and Alloys, Nucleation, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Grain size, Electronic, Optical and Magnetic Materials, Dendrite (crystal), Temperature gradient, 0103 physical sciences, Ceramics and Composites, Surface roughness, Texture (crystalline), Composite material, 0210 nano-technology, Inconel

Abstract

In addition to design geometry, surface roughness, and solid-state phase transformation, solidification microstructure plays a crucial role in controlling the performance of additively manufactured components. Crystallographic texture, primary dendrite arm spacing (PDAS), and grain size are directly correlated to local solidification conditions. We have developed a new melt-scan strategy for inducing site specific, on-demand control of solidification microstructure. We were able to induce variations in grain size (30 μm–150 μm) and PDAS (4 μm - 10 μm) in Inconel 718 parts produced by the electron beam additive manufacturing system (Arcam ® ). A conventional raster melt-scan resulted in a grain size of about 600 μm. The observed variations in grain size with different melt-scan strategies are rationalized using a numerical thermal and solidification model which accounts for the transient curvature of the melt pool and associated thermal gradients and liquid-solid interface velocities. The refinement in grain size at high cooling rates (>10 4 K/s) is also attributed to the potential heterogeneous nucleation of grains ahead of the epitaxially growing solidification front. The variation in PDAS is rationalized using a coupled numerical-theoretical model as a function of local solidification conditions (thermal gradient and liquid-solid interface velocity) of the melt pool.

Published

2017

7. Mechanical properties and microstructure of 316L stainless steel produced by hybrid manufacturing

Author

Kyle Saleeby, Lonnie J. Love, Thomas R. Kurfess, Thomas Feldhausen, and Narendran Raghavan

Subjects

0209 industrial biotechnology, Subtractive color, business.product_category, Materials science, business.industry, Metals and Alloys, ComputerApplications_COMPUTERSINOTHERSYSTEMS, 02 engineering and technology, Microstructure, Industrial and Manufacturing Engineering, Computer Science Applications, Machine tool, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Machining, Modeling and Simulation, Component (UML), Ceramics and Composites, Deposition (phase transition), Process engineering, business, Porosity, Near net shape

Abstract

Hybrid manufacturing is a combination of additive (deposition) and subtractive (machining) manufacturing in a single machine tool. Such a system can be used for near net shape manufacturing and component repair using either similar or dissimilar materials. Integrated into a single system, transition between additive and subtractive manufacturing can occur immediately and be leveraged to generate large components by alternating between the processes. This investigation shows how the interleaved capabilities can reduce overall cycle time by up to 68 %, improve average relative elongation to failure by 71 %, and reduce the average relative porosity fraction by 83 % when compared to traditional additive manufactured components. Results from this investigation builds the foundation needed for hybrid manufacturing to be applicable towards the manufacture of large complex components such as nosecones and marine propulsors.

Published

2021

8. Numerical modeling of heat-transfer and the influence of process parameters on tailoring the grain morphology of IN718 in electron beam additive manufacturing

Author

Michael M. Kirka, Narendran Raghavan, Ryan R. Dehoff, John A. Turner, Sreekanth Pannala, Srdjan Simunovic, Neil N. Carlson, and S. Suresh Babu

Subjects

010302 applied physics, Equiaxed crystals, Materials science, Electron-beam additive manufacturing, Polymers and Plastics, Metallurgy, Metals and Alloys, 02 engineering and technology, Welding, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Casting, Electronic, Optical and Magnetic Materials, law.invention, Superalloy, law, 0103 physical sciences, Ceramics and Composites, Texture (crystalline), Composite material, 0210 nano-technology, Inconel

Abstract

The fabrication of 3-D parts from CAD models by additive manufacturing (AM) is a disruptive technology that is transforming the metal manufacturing industry. The correlation between solidification microstructure and mechanical properties has been well understood in the casting and welding processes over the years. This paper focuses on extending these principles to additive manufacturing to understand the transient phenomena of repeated melting and solidification during electron beam powder melting process to achieve site-specific microstructure control within a fabricated component. In this paper, we have developed a novel melt scan strategy for electron beam melting of nickel-base superalloy (Inconel 718) and also analyzed 3-D heat transfer conditions using a parallel numerical solidification code (Truchas) developed at Los Alamos National Laboratory. The spatial and temporal variations of temperature gradient (G) and growth velocity (R) at the liquid-solid interface of the melt pool were calculated as a function of electron beam parameters. By manipulating the relative number of voxels that lie in the columnar or equiaxed region, the crystallographic texture of the components can be controlled to an extent. The analysis of the parameters provided optimum processing conditions that will result in columnar to equiaxed transition (CET) during the solidification. The results from the numerical simulations were validated by experimental processing and characterization thereby proving the potential of additive manufacturing process to achieve site-specific crystallographic texture control within a fabricated component.

Published

2016

9. Microstructure Development in Electron Beam-Melted Inconel 718 and Associated Tensile Properties

Author

Michael M. Kirka, Narendran Raghavan, Ryan R. Dehoff, Francisco Medina, S. Suresh Babu, and Kinga A. Unocic

Subjects

010302 applied physics, Materials science, Precipitation (chemistry), Metallurgy, General Engineering, 02 engineering and technology, Laves phase, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Carbide, Superalloy, 0103 physical sciences, Ultimate tensile strength, General Materials Science, Elongation, 0210 nano-technology, Inconel

Abstract

During the electron beam melting (EBM) process, builds occur at temperatures in excess of 800°C for nickel-base superalloys such as Inconel 718. When coupled with the temporal differences between the start and end of a build, a top-to-bottom microstructure gradient forms. Characterized in this study is a microstructure gradient and associated tensile property gradient common to all EBM Inconel 718 builds, the extent of which is dependent on build geometry and the specifics of a build’s processing history. From the characteristic microstructure elements observed in EBM Inconel 718 material, the microstructure gradient can be classified into three distinct regions. Region 1 (top of a build) is comprised of a cored dendritic structure that includes carbides and Laves phase within the interdendritic regions. Region 2 is an intermediate transition zone characterized by a diffuse dendritic structure, dissolution of the Laves phase, and precipitation of $$\delta $$ needle networks within the interdendritic regions. The bulk structure (Region 3) is comprised of a columnar grain structure lacking dendritic characteristics with $$\delta $$ networks having precipitated within the grain interiors. Mechanically, at both 20°C and 650°C, the yield strength, ultimate tensile strength, and elongation at failure exhibit the general trend of increasing with increasing build height.

Published

2016

10. Fluid Dynamics Effects on Microstructure Prediction in Single Laser Tracks for Additive Manufacturing

Author

Adrian Sabau, Yuan Lang, Narendran Raghavan, Srdjan Simunovic, John Turner, and Vipul Gupta

Published

2018

11. Controlling microstructure in deposits fabricated using powder blown direct energy deposition technique

Author

Narendran Raghavan, Ryan R. Dehoff, and Brian H. Jordan

Subjects

Materials science, Metallurgy, Microstructure, Deposition (chemistry), Energy (signal processing)

Published

2018

12. Processing-Microstructure Relationships From 3D Characterization of Additively Manufactured Metals

Author

McLean P. Echlin, Ryan R. Dehoff, William C. Lenthe, Andrew T. Polonsky, Michael M. Kirka, Narendran Raghavan, and Tresa M. Pollock

Subjects

Materials science, Metallurgy, Microstructure, Instrumentation, Characterization (materials science)

Published

2019

13. Corrigendum to 'Numerical modeling of heat-transfer and the influence of process parameters on tailoring the grain morphology of IN718 in electron beam additive manufacturing' [Acta Mater. 112C (2016) 303–314]

Author

John A. Turner, Sreekanth Pannala, Narendran Raghavan, Neil N. Carlson, S. Suresh Babu, Srdjan Simunovic, Michael M. Kirka, and Ryan R. Dehoff

Subjects

0209 industrial biotechnology, Morphology (linguistics), Electron-beam additive manufacturing, Materials science, Polymers and Plastics, Metals and Alloys, Numerical modeling, Nanotechnology, 02 engineering and technology, 021001 nanoscience & nanotechnology, Electronic, Optical and Magnetic Materials, 020901 industrial engineering & automation, Scientific method, Heat transfer, Ceramics and Composites, Composite material, 0210 nano-technology

Published

2017