A brief survey of sensing for metal-based powder bed fusion additive manufacturing

Foster, Bryant; Reutzel, Edward W.; Nassar, Abdalla R.; Dickman, Corey J.; Hall, B. D.

doi:10.1117/12.2180654

Cited by 27 publications

(15 citation statements)

References 6 publications

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“…Particle drag during the spreading process was also reported experimentally by Foster et al [38] and Abdelrahman et al [39].…”

Section: Spread Powder Layer Defectssupporting

confidence: 70%

The influence of material properties and process parameters on the spreading process in additive manufacturing

Shaheen,

Thornton,

Luding

et al. 2020

Preprint

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Laser powder bed fusion (LPBF) is an additive manufacturing (AM) technology. To achieve high product quality, the powder is best spread as a uniform, dense layer. The challenge for LPBF manufacturers is to develop a spreading process that can produce a consistent layer quality for the many powders used, which show considerable differences in spreadability. Therefore, we investigate the influence of material properties, process parameters and the type of spreading tool on the layer quality. The discrete particle method is used to simulate the spreading process and to define metrics to evaluate the powder layer characteristics. We found that particle shape and surface roughness in terms of rolling resistance and interparticle sliding friction as well as particle cohesion all have a major (sometimes surprising) influence on the powder layer quality: more irregular shaped particles, rougher particle surfaces and/or higher interfacial cohesion usually, but not always, lead to worse spreadability. Our findings illustrate that there is a trade-off between material properties and process parameters. Increasing the spreading speed decreases layer quality for non-and weakly cohesive powders, but improves it for strongly cohesive ones. Using a counter-clockwise rotating roller as * Corresponding author.

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“…Particle drag during the spreading process was also reported experimentally by Foster et al [38] and Abdelrahman et al [39].…”

Section: Spread Powder Layer Defectssupporting

confidence: 70%

The influence of material properties and process parameters on the spreading process in additive manufacturing

Shaheen,

Thornton,

Luding

et al. 2020

Preprint

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“…Objective 1: Develop and apply a spectral graph theoretic approach to monitor the build condition in LPBF from the data gathered by the aforementioned three sensors. The intent is to detect the onset of deleterious phenomena such as unexpected variations in the thermal history (cooling rate) which would lead to inconsistent properties [13][14][15]. In the worst case, these may ultimately result in build failures.…”

Section: Sensor-based Build Condition Monitoring In Laser Powder Bed mentioning

confidence: 99%

“…Tapia and Elwany [40] have conducted a comprehensive review of sensor-based process monitoring approaches, specifically focused on metal AM processes. More recently, Foster et al [15], Purtonen et al [41], Mani et al [22], Everton et al [42], and Grasso and Colosimo [4] provided excellent reviews of the status quo of sensing and monitoring focused in metal AM. However, there is a persistent gap in analytical approaches to synthesize this data and extract patterns that correlate with specific process conditions (build status) and defects [43].…”

Section: Sensor-based Monitoring In Powder Bed Fusionmentioning

confidence: 99%

Sensor-Based Build Condition Monitoring in Laser Powder Bed Fusion Additive Manufacturing Process Using a Spectral Graph Theoretic Approach

Montazeri

Rao

2018

Journal of Manufacturing Science and Engineering

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The goal of this work is to monitor the laser powder bed fusion (LPBF) process using an array of sensors so that a record may be made of those temporal and spatial build locations where there is a high probability of defect formation. In pursuit of this goal, a commercial LPBF machine at the National Institute of Standards and Technology (NIST) was integrated with three types of sensors, namely, a photodetector, high-speed visible camera, and short wave infrared (SWIR) thermal camera with the following objectives: (1) to develop and apply a spectral graph theoretic approach to monitor the LPBF build condition from the data acquired by the three sensors; (2) to compare results from the three different sensors in terms of their statistical fidelity in distinguishing between different build conditions. The first objective will lead to early identification of incipient defects from in-process sensor data. The second objective will ascertain the monitoring fidelity tradeoff involved in replacing an expensive sensor, such as a thermal camera, with a relatively inexpensive, low resolution sensor, e.g., a photodetector. As a first-step toward detection of defects and process irregularities that occur in practical LPBF scenarios, this work focuses on capturing and differentiating the distinctive thermal signatures that manifest in parts with overhang features. Overhang features can significantly decrease the ability of laser heat to diffuse from the heat source. This constrained heat flux may lead to issues such as poor surface finish, distortion, and microstructure inhomogeneity. In this work, experimental sensor data are acquired during LPBF of a simple test part having an overhang angle of 40.5 deg. Extracting and detecting the difference in sensor signatures for such a simple case is the first-step toward in situ defect detection in additive manufacturing (AM). The proposed approach uses the Eigen spectrum of the spectral graph Laplacian matrix as a derived signature from the three different sensors to discriminate the thermal history of overhang features from that of the bulk areas of the part. The statistical accuracy for isolating the thermal patterns belonging to bulk and overhang features in terms of the F-score is as follows: (a) F-score of 95% from the SWIR thermal camera signatures; (b) 83% with the high-speed visible camera; (c) 79% with the photodetector. In comparison, conventional signal analysis techniques—e.g., neural networks, support vector machines, linear discriminant analysis were evaluated with F-score in the range of 40–60%.

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“…Bauza et al 19 noted that the dimensional errors were generally repeatable across builds, alluding to the fact that tuning build parameters could minimize these errors. However, tuning build parameters for every part would require repeated builds and in-depth analysis of the results of those builds, as well as in situ monitoring of the build process 22 , which may be time and cost prohibitive.…”

Section: Previous Studiesmentioning

confidence: 99%

Repeatability in Performance of Micro Cooling Geometries Manufactured with Laser Powder Bed Fusion

Kirsch

Snyder

Stimpson

et al. 2017

53rd AIAA/SAE/ASEE Joint Propulsion Conference

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Stringent regulations on aircraft engine emissions introduce a series restrictions on weight, size, and durability of all engine components to increase efficiency. In the hot section of a gas turbine engine, for example, airfoil internal cooling schemes must provide more efficient cooling with minimal mass flow. Such a requirement drives the cooling channels' size to the micro scale. One new tool currently being explored to achieve industry-required efficiencies can be found in advanced manufacturing techniques, such as laser powder bed fusion. However, as with all new technologies, the laser powder bed fusion process must be thoroughly investigated, fully understood, and achieve reliable and repeatable results before the process is widely implemented for gas turbine airfoils. This paper provides experimental results on the dimensions, as well as pressure loss and heat transfer performance, of microchannels manufactured using laser powder bed fusion; the microchannels mimic those suitable for airfoil internal cooling. Variability in the performance will be quantified for different builds, as well as for different materials. Nomenclature AM Additive manufacturing As surface area CT X-ray computed tomography Dh hydraulic diameter f friction factor, ΔP•(1/2•ρ•U2)-1 •Dh•L-1 h heat transfer coefficient, Q•(As•ΔTlm)-1 k thermal conductivity L-PBF laser powder bed fusion Nu Nusselt number, h•Dh•k-1 Re Reynolds number, U•Dh•ν-1 ΔTlm log mean temperature difference U mean channel velocity ϵ sand grain roughness λ wavelength ν kinematic viscosity I. Introduction The potential of metal additive manufacturing (AM) to transform the aerospace industry is limitless. Key benefits of the manufacturing technology include weight, material, and lead time savings, in addition to a more open design space well-suited to shape and topology optimization. Despite the continual improvements in the industry, however, the manufacturing method requires further vetting, especially in the realm of geometric repeatability and holding tolerances of micro-sized features.

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A brief survey of sensing for metal-based powder bed fusion additive manufacturing

Cited by 27 publications

References 6 publications

The influence of material properties and process parameters on the spreading process in additive manufacturing

The influence of material properties and process parameters on the spreading process in additive manufacturing

Sensor-Based Build Condition Monitoring in Laser Powder Bed Fusion Additive Manufacturing Process Using a Spectral Graph Theoretic Approach

Repeatability in Performance of Micro Cooling Geometries Manufactured with Laser Powder Bed Fusion

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