Your search keyword '"Colton Katsarelis"' showing total 12 results

1. Laser powder directed energy deposition (LP-DED) NASA HR-1 alloy: Laser power and heat treatment effects on microstructure and mechanical properties

Author

Arash Soltani-Tehrani, Poshou Chen, Colton Katsarelis, Paul Gradl, Shuai Shao, and Nima Shamsaei

Subjects

Additive manufacturing, Laser power, Laser spot size, NASA HR-1, Iron-based superalloys, Industrial engineering. Management engineering, T55.4-60.8

Abstract

This study investigated the microstructure and tensile properties of the NASA HR-1 (Fe-Ni-Cr) alloy using the laser powder directed energy deposition (LP-DED) process. Laser power and spot size were varied for deposition, and it was noted that low laser power could result in higher cooling rates and finer microstructure. The melt pool depth and width and the defect content increased with the increase in laser power. Out of several laser power (i.e., 350, 750, 1070, 2000, and 2620 W), the samples deposited using 750 W demonstrated the highest material density. In addition, the effects of heat treatment on the microstructure and tensile properties were investigated. It was found that a heat treatment schedule consisting of stress relief, homogenization, solution treatment, and aging could thoroughly homogenize the microstructure (i.e., remove the as-solidified dendritic microstructure), result in relatively uniform, equiaxed grains, and increase the material hardness. Importantly, this heat treatment schedule efficiently reduced titanium segregation, preventing the formation of deleterious needle-shaped η (Ni3Ti) precipitates in NASA HR-1, known to be detrimental to mechanical properties and resulted in almost comparable tensile properties with varying laser power.

Published

2022

2. Microstructure and hardness comparison of as-built inconel 625 alloy following various additive manufacturing processes

Author

Ariel Gamon, Edel Arrieta, Paul R. Gradl, Colton Katsarelis, Lawrence E. Murr, Ryan B. Wicker, and Francisco Medina

Subjects

Inconel 625, Microstructure comparisons, Microindentation hardness, Additive manufacturing techniques: WAAM, L-PBF, LP-DED, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Experimental examples of as-built microstructures and associated microindentation hardnesses (HV) for a wide range of metal additive manufacturing (AM) processes for Inconel 625 alloy are presented in this research paper. These processes included cold spray, laser powder bed fusion, wire arc additive manufacturing, electron beam directed energy deposition, laser hot wire, binder jetting, laser power directed energy deposition, electron beam melting, and laser wire directed energy deposition. Microstructures ranged from impact bonded, flattened 625 alloy grains containing microdendrites and dislocations, having a microindentation hardness of HV 590 for cold spray, to large, equiaxed grains for binder jet-printed components having a microindentation hardness of HV 180. Electron and laser beam melt-related processes, including wire and powder feeds, produced varying sizes of columnar grains with parallel and cellular arrays of microdendrites, having microindentation hardnesses ranging from HV 304 to HV 228. Delta phase precipitate needles were also produced in laser-powered directed energy deposition microstructures along with columns of gamma double-prime precipitates for electron beam melting. The results demonstrate a range of AM processes applications and strategies to produce as-built and surface-modified Inconel 625 alloy products and components. These results demonstrate differences in the microstructure from the various AM processes and considerations for use in end use applications.

Published

2021

3. Comprehensive and Comparative Heat Treatment of Additively Manufactured Inconel 625 Alloy and Corresponding Microstructures and Mechanical Properties

Author

Victoria Luna, Leslie Trujillo, Ariel Gamon, Edel Arrieta, Lawrence E. Murr, Ryan B. Wicker, Colton Katsarelis, Paul R. Gradl, and Francisco Medina

Subjects

Inconel 625, additive manufacturing techniques, post-process heat treatment, microstructures, microindentation hardness, tensile properties, Production capacity. Manufacturing capacity, T58.7-58.8

Abstract

This study examines and compares the microstructures, Vickers microindentation hardness, and mechanical properties for additively manufactured (AM) samples built by a variety of AM processes: wire arc AM (WAAM), electron beam powder bed fusion (EB-PBF), laser wire direct energy deposition (LW-DED), electron beam direct energy deposition (EB-DED), laser-powered direct energy deposition (LP-DED), and laser powder bed fusion (L-PBF). These AM process samples were post-processed and heat-treated by stress relief annealing at 1066 °C, HIP at 1163 °C, and solution annealing treatment at 1177 °C. The resulting microstructures and corresponding microindentation hardnesses were examined and compared with the as-built AM process microstructures and hardnesses. Fully heat-treated AM process samples were mechanically tested to obtain tensile properties and were also evaluated and compared. Principal findings in this study were that high-temperature heat treatment >1100 °C of AM process-built samples was dominant and exhibited recrystallized, equiaxed grains containing fcc {111} annealing twins and second phase particles independent of the AM process, in contrast to as-built columnar/dendritic structures. The corresponding yield stress values ranged from 285 MPa to 371 MPa, and elongations ranged from 52% to 70%, respectively. Vickers microindentation hardnesses (HV) over this range of heat-treated samples varied from HV 190 to HV 220, in contrast to the as-built samples, which varied from HV 191 to HV 304.

Published

2022

4. Welding of Crack Sensitive Aluminum Alloys for Liquid Rocket Propulsion Applications

Author

William Evans, Tessa Fedotowsky, Ben Williams, Gabriel Demeneghi, Claire Handley, Colton Katsarelis, Paul Gradl, Darren Tinker, Nick Bagshaw, Jeff Lints, and Alex Yearsly

Subjects

Metals and Metallic Materials

Abstract

In this welding test campaign, electron beam welding (EBW) and manual gas tungsten arc welding (GTAW) processes were utilized to join an additively manufactured aluminum alloy nozzle to a wrought aluminum flange. Both aluminum alloys were 6061, which in their conventional form are susceptible to solidification cracking issues. The AM nozzle utilized a novel high-performance modified version of 6061 which exhibits crack resistant properties during the AM process and during welding. When manually conducting GTAWs a filler wire with the same modified version of 6061 was utilized to weld different combinations of 6061 coupons (either modified or unmodified). Due to the grain refinement technology in the modified 6061, either as filler material or base material, there was complete elimination of weld solidification cracking. During EBW development a combination of wrought 6061 with a modified and additively manufactured 6061 was investigated. The EBWs developed exhibited no crack like defects. Each weld development program utilized non-destructive evaluation, metallography, and mechanical testing to determine the final weld acceptance. Mechanical testing involved hardness evaluation and tension testing on welded coupons. Both welding techniques were successfully developed and exhibited adequate properties for the final test articles and met all requirements of the development campaign. These welds were ultimately developed to be utilized on a set of all-aluminum liquid rocket nozzles to demonstrate additively manufactured aluminum alloys for propulsion applications. These aluminum nozzles were tested at NASA Marshall Space Flight Center’s hot fire test facility and subsequently underwent a test campaign involving a variety of chamber pressures and liquid propellant combinations. Following the hot fire test campaign each weldment was investigated for post operation performance and any defects that may have evolved during testing.

Published

2024

5. Handbook for Additively Manufactured Materials: Microstructure, Properties, and Fractography

Author

Colton Katsarelis, Kelsay Neely, Paul Gradl, Alison Park, and Nima Shamsaei

Subjects

Metals and Metallic Materials

Abstract

As the additive manufacturing (AM) industry has grown and the processes have matured more alloys have been adapted to the various AM processes. Understanding the microstructure and properties of these AM alloys is important in designing parts that perform appropriately in application. For decades materials handbooks have been informative references for designers and engineers alike to know what properties and microstructures to expect in alloys produced by other forms of manufacturing. AM alloy references for properties and microstructures have been largely limited to literature that may not be subject to the same industry standard heat treatments or in standard process parameters. NASA has worked with partners to characterize various commercially available AM alloys with a high degree of traceability. This work aims utilize industry-relevant, traceable datasets to develop a new handbook for AM alloys to better inform designers and engineers of the microstructures, fractures, and first order properties from over 30 AM alloys produced across the industry.

Published

2023

6. Additive Manufacturing Process Development DOE for NASA HR-1 using Laser Blown Powder Directed Energy Deposition

Author

Parker Shake, William Evans, and Colton Katsarelis

Subjects

Lasers and Masers

Abstract

NASA HR-1 is a Fe-Ni-Cr alloy that is used for high pressure hydrogen applications such as rocket engines, energy, and oil and gas. This investigation was focused on conducting a design of experiment program aimed at mapping the parameter process window for NASA HR-1 using the laser blown powder directed energy deposition (LP-DED) process. A two phased design of experiments (DOE), the first phase of the experiment was focused on optimizing single bead tracks while the second phase of the experiment was focused on optimizing bead overlap hatching in a multi pass bead build up. During the first phase of the deposition parameters, namely laser power, travel speed, and powder feed rate were varied. A down selection from the single bead parameter set was made and hatching experiments were conducted that focused on the overlap distance. In this paper the approach for conducting the DOE and results are discussed. The results focused on measurement of bead geometry, the as-built microstructural evolution, and porosity within the samples. The team at MSFC saw a variety of results across the process map created during the first phase of experimentation and were able to down select a parameter that created an optimal bead shape with a minimal amount of build porosity. It was determined that laser power and robot travel speed were the most sensitive parameters. The results from this investigation will inform future laser powder directed energy deposition parameter developments.

Published

2023

7. SLM Inconel 625 Thin Section Study

Author

Baxter Barnes, Travis Palm, Samantha Marcella, Colton Katsarelis, and Mallory James

Subjects

Structural Mechanics

Published

2022

8. Selection and Overview of Additive Manufactured Metals and Metal Alloys

Author

Paul R. Gradl, Omar R. Mireles, Colton Katsarelis, Christopher S. Protz, Po-Shou Chen, Daniel P. Dennies, Jonathan Tylka, Ali Hemmasian-Ettefagh, and Shengmin Guo

Published

2022

9. Mechanical properties of laser powder directed energy deposited NASA HR-1 superalloy: Effects of powder reuse and part orientation

Author

Arash Soltani-Tehrani, Poshou Chen, Colton Katsarelis, Paul Gradl, Shuai Shao, and Nima Shamsaei

Subjects

Mechanical Engineering, Building and Construction, Civil and Structural Engineering

Published

2023

10. Microstructure and hardness comparison of as-built inconel 625 alloy following various additive manufacturing processes

Author

Lawrence E Murr, Colton Katsarelis, Ariel Gamon, Edel Arrieta, Paul R. Gradl, Ryan B. Wicker, and Francisco Medina

Subjects

Equiaxed crystals, Additive manufacturing techniques: WAAM, Materials science, Microstructure comparisons, Alloy, Gas dynamic cold spray, LP-DED, Inconel 625, engineering.material, Laser, Microstructure, law.invention, law, engineering, TA401-492, Deposition (phase transition), L-PBF, General Materials Science, Laser power scaling, Composite material, Materials of engineering and construction. Mechanics of materials, Microindentation hardness

Abstract

Experimental examples of as-built microstructures and associated microindentation hardnesses (HV) for a wide range of metal additive manufacturing (AM) processes for Inconel 625 alloy are presented in this research paper. These processes included cold spray, laser powder bed fusion, wire arc additive manufacturing, electron beam directed energy deposition, laser hot wire, binder jetting, laser power directed energy deposition, electron beam melting, and laser wire directed energy deposition. Microstructures ranged from impact bonded, flattened 625 alloy grains containing microdendrites and dislocations, having a microindentation hardness of HV 590 for cold spray, to large, equiaxed grains for binder jet-printed components having a microindentation hardness of HV 180. Electron and laser beam melt-related processes, including wire and powder feeds, produced varying sizes of columnar grains with parallel and cellular arrays of microdendrites, having microindentation hardnesses ranging from HV 304 to HV 228. Delta phase precipitate needles were also produced in laser-powered directed energy deposition microstructures along with columns of gamma double-prime precipitates for electron beam melting. The results demonstrate a range of AM processes applications and strategies to produce as-built and surface-modified Inconel 625 alloy products and components. These results demonstrate differences in the microstructure from the various AM processes and considerations for use in end use applications.

Published

2021

11. Process Development and Hot-fire Testing of Additively Manufactured NASA HR-1 for Liquid Rocket Engine Applications

Author

Paul R. Gradl, Christopher S. Protz, Thomas W. Teasley, Po Chen, and Colton Katsarelis

Subjects

Fire test, Materials science, business.industry, Liquid-propellant rocket, Process development, Aerospace engineering, business

Published

2021

12. Influence of interlayers on the interfacial behavior of Ag films on polymer substrates

Author

Megan J. Cordill, Michael Paulitsch, Colton Katsarelis, Barbara Putz, Alice Lassnig, and Marian S. Kennedy

Subjects

Materials Chemistry, Metals and Alloys, Surfaces and Interfaces, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Published

2022