Your search keyword '"Chad Beamer"' showing total 5 results

1. Microstructure and mechanical properties of laser powder bed fusion Ti-6Al-4V after HIP treatments with varied temperatures and cooling rates

Author

Nicholas Derimow, Jake T. Benzing, Howie Joress, Austin McDannald, Ping Lu, Frank W. DelRio, Newell Moser, Matthew J. Connolly, Alec I. Saville, Orion L. Kafka, Chad Beamer, Ryan Fishel, Suchismita Sarker, Chris Hadley, and Nik Hrabe

Subjects

Additive manufacturing, Ti-6Al-4V, Microstructure, Heat treatment, Laser powder bed fusion, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

This work investigated non-standard HIP cycles for PBF-L Ti-6Al-4V and characterized microstructure and tensile properties to compare between material that originated from the same build. For 920°C, faster cooling rates (100°C/min, 2000°C/min) were found to promote bi-lamellar α microstructure, while the 2000°C/min cooling rate improved the strength. For HIP with lower temperature (800°C, 200 MPa), coarsening was minimized resulting in strength improvement. The slow cooling rate (12°C/min) showed the highest strength as faster rates increased the amount of orthorhombic martensite (α″). For HIP with higher temperature (1050°C), the as-built crystallographic texture was reduced and equiaxed prior-β grain morphology resulted, leading to more isotropic tensile properties. However, the cooling rate (2000°C/min) was not enough to prevent formation of grain boundary α, which reduced strength and elongation. Machine learning was carried out on the dataset via Principal Component Analysis (PCA) to reduce the dimensionality of the parameters and microstructural features.

Published

2024

2. Productivity enhancement of laser powder bed fusion using compensated shelled geometries and hot isostatic pressing

Author

Anton Du Plessis, Bharat Yelamanchi, Christian Fischer, James Miller, Chad Beamer, Kirk Rogers, Pedro Cortes, Johan Els, and Eric MacDonald

Subjects

Productivity enhancement, Laser powder bed fusion, Ti6Al4V, Hot isostatic pressing, Shelled powder metallurgy, Additive manufacturing, Industrial engineering. Management engineering, T55.4-60.8

Abstract

In laser powder bed fusion (L-PBF), the mechanical performance and especially fatigue properties of fabricated parts are significantly improved by hot isostatic pressing (HIP) as the density increases (pores are closed) and the microstructure improves. HIP ensures consistent and defect-free material, and consequently, this high temperature and high pressure process is often a requirement for safety-critical aerospace applications. The use of HIP to directly consolidate intentionally-unmelted interior powder in a L-PBF part was recently demonstrated. By confining the laser melting to only the outer shell (contour) of the structure, L-PBF production times can be dramatically reduced. A subsequent HIP cycle, which may be mandatory for reliability reasons, and therefore does not add additional costs, is then used to densify the entire structure. Production rates and energy efficiencies can therefore be improved in this way. This study explores the effect of relying on the HIP process to consolidate interior sections of test coupons, for which micro computed tomography (microCT), process simulation and tensile tests were conducted. MicroCT of coupons with varying shell thicknesses identify the minimum shell thickness required; and provide indications of the shrinkage ratio as a function of powder content relative to shell thickness. Preliminary results are included in which the shrinkage can be compensated for during design, by way of a “bloated cube” which collapses to a nominal cube geometry after HIP. The mechanical evaluation of the consolidated shelled parts indicates that their tensile performance is equivalent to those observed on fully dense printed parts. Up to an order of magnitude faster build rates are possible and any resulting shrinkage or distortion can be offset at design.

Published

2021

3. The Role of Isostatic Pressing in Large-Scale Production of Solid-State Batteries

Author

Marm Dixit, Chad Beamer, Ruhul Amin, James Shipley, Richard Eklund, Nitin Muralidharan, Lisa Lindqvist, Anton Fritz, Rachid Essehli, Mahalingam Balasubramanian, and Ilias Belharouak

Subjects

Fuel Technology, Renewable Energy, Sustainability and the Environment, Chemistry (miscellaneous), Materials Chemistry, Energy Engineering and Power Technology

Published

2022

4. Influence of Machining on Low Temperature Surface Hardening of Stainless Steel

Author

Chad Beamer, Andreas Karl, and Ulli Oberste-Lehn

Subjects

Materials science, Machining, Metallurgy, Case hardening

Abstract

Austenitic stainless steels are carburized or nitrided (i.e., surface hardened) at low temperatures in order to maintain their superior corrosion resistance. Treatment temperature must be low enough to prevent precipitation in the diffusion zone, yet high enough to allow sufficient diffusion depths to meet design specifications. At these temperatures, prior machining processes can have a significant effect not only on diffusion, but also the surface hardness and corrosion resistance achieved. This paper presents practical examples showing how cutting, grinding, honing, and polishing processes influence the results of low temperature surface hardening treatments for stainless steel parts. It also discusses the influence of surface deformation and finish.

Published

2019

5. Productivity enhancement of laser powder bed fusion using compensated shelled geometries and hot isostatic pressing

Author

James Miller, Christian Fischer, Anton du Plessis, Eric MacDonald, Johan Els, Pedro Luiz Côrtes, Chad Beamer, Kirk Rogers, and Bharat Yelamanchi

Subjects

Materials science, Additive manufacturing, Industrial engineering. Management engineering, Mechanical Engineering, Hot isostatic pressing, Shelled powder metallurgy, Ti6Al4V, Shell (structure), T55.4-60.8, Microstructure, Industrial and Manufacturing Engineering, Mechanics of Materials, Laser powder bed fusion, Ultimate tensile strength, Cube, Composite material, Process simulation, Engineering (miscellaneous), Order of magnitude, Productivity enhancement, Shrinkage

Abstract

In laser powder bed fusion (L-PBF), the mechanical performance and especially fatigue properties of fabricated parts are significantly improved by hot isostatic pressing (HIP) as the density increases (pores are closed) and the microstructure improves. HIP ensures consistent and defect-free material, and consequently, this high temperature and high pressure process is often a requirement for safety-critical aerospace applications. The use of HIP to directly consolidate intentionally-unmelted interior powder in a L-PBF part was recently demonstrated. By confining the laser melting to only the outer shell (contour) of the structure, L-PBF production times can be dramatically reduced. A subsequent HIP cycle, which may be mandatory for reliability reasons, and therefore does not add additional costs, is then used to densify the entire structure. Production rates and energy efficiencies can therefore be improved in this way. This study explores the effect of relying on the HIP process to consolidate interior sections of test coupons, for which micro computed tomography (microCT), process simulation and tensile tests were conducted. MicroCT of coupons with varying shell thicknesses identify the minimum shell thickness required; and provide indications of the shrinkage ratio as a function of powder content relative to shell thickness. Preliminary results are included in which the shrinkage can be compensated for during design, by way of a “bloated cube” which collapses to a nominal cube geometry after HIP. The mechanical evaluation of the consolidated shelled parts indicates that their tensile performance is equivalent to those observed on fully dense printed parts. Up to an order of magnitude faster build rates are possible and any resulting shrinkage or distortion can be offset at design.

Published

2021