Variation of texture anisotropy and hardness with build parameters and wall height in directed-energy-deposited 316L steel

Chechik, Lova; Boone, Nicholas Andrew; Stanger, Leigh Russell; Honniball, Peter D.; Freeman, Felicity; Baxter, Gavin; Willmott, Jon R.; Todd, Iain

doi:10.1016/j.addma.2020.101806

Cited by 11 publications

(10 citation statements)

References 38 publications

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“…Earlier work by Bi (2006a), had reported a similar effect on single-walled 316 L steel samples, and also showed corresponding trends in microstructure and hardness. A further development by Chechik et al (2020) used side-view imaging to monitor DED of thin walled samples (6 hatches, 2.7 mm thickness), and found cooling rate to be higher close to the baseplate, as expected from a smaller melt pool. This raises the possibility that different machine set-ups and clamping strategies could change the strength of this heat sink and cause differences in the manufactured product.…”

Section: Introductionmentioning

confidence: 93%

Calibrated Closed-Loop Control to Reduce the Effect of Geometry on Mechanical Behaviour in Directed Energy Deposition

et al. 2022

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Section: Introductionmentioning

confidence: 93%

Calibrated Closed-Loop Control to Reduce the Effect of Geometry on Mechanical Behaviour in Directed Energy Deposition

et al. 2022

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“…The hopper was loaded with approximately 3 kg of GA316 powder and > 200 g of powder was run through the pipework to allow the system to stabilise before collecting data. The maximum hopper rotation speed is 10 rpm, and data was collected at 0.5, 1.0, 1.5, 2.0, 2.5 and 3.0 rpm, covering the standard range of powder flow rates found in literature [14][15][16] . The data was collected as a single run, with 5 min at each turntable speed stepping up from 0.5 rpm to 3.0 rpm.…”

Section: Hopper Flow Measurementsmentioning

confidence: 99%

“…From literature, powder flow rate is generally between 5 g/min and 20 g/min in DED, although some use flow rates outside this range [14][15][16] . As the hoppers are volumetrically controlled, the material density and packing density have an influence on the volume of powder required to achieve a target mass flow rate.…”

Section: Introductionmentioning

confidence: 99%

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Multi-Faceted Monitoring of Powder Flow Rate Variability in Directed Energy Deposition

Freeman¹,

Thomas²,

Chechik³

et al. 2021

SSRN Journal

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Powder flow rate is a key parameter in Directed Energy Deposition (DED) processes. During a typical build, if powder flow rate is reduced for just 1 second, 30 mm of melt track is affected. Consequently, even a small variation in powder flow rate can have significant implications on build quality. In this work, the powder flow stability for different types of 316 L steel powders was quantified using a combination of methodologies including offline weight measurements, flow imaging, in-situ build data and coaxial melt pool imaging. Flow rate oscillation was observed, correlated with the periodicity of powder hopper turntable rotation, at sufficient magnitude to cause build quality effects and be identifiable in coaxial melt pool imaging. The implications of flow rate variation on the use of melt pool imaging for closed-loop control are discussed.

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“…The mechanical properties of a metal are dependent on the scale of the microstructure (including grain size, dendrite arm spacing and precipitate dispersion) and the heat treatments experienced 8 . The scale of the microstructure is dependent on the cooling rate during solidi cation, which can be correlated with the melt pool size 9,10 . This leaves many values which could be controlled to improve component homogeneity.…”

Section: Introductionmentioning

confidence: 99%

Controlling grain structure in metallic additive manufacturing using a simple, inexpensive process control system

Chechik

Goodall

Christofidou

et al. 2023

Preprint

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Additive manufacturing (AM), commonly termed 3D printing, is a revolutionary manufacturing technology with great industrial relevance in the aerospace, medical and automotive sectors. Metallic AM allows creation of complex intricate parts and repair of large components; however, certification is currently a concern due to lack of process consistency. A simple, inexpensive process control system was developed and integrated, reducing variability in melt pool fluctuation and improving microstructural homogeneity of components. Remnant microstructural variation can be explained by the change in heat flow mechanism with geometry. The grain area variability was reduced by up to 94% at a fraction of the cost of a typical thermal camera, with control software written in-house and made publically available. This decreases the barrier to implementation for process feedback control, which can be implemented in many manufacturing processes, from polymer AM to injection moulding to inert-gas heat treatment.

show abstract

Variation of texture anisotropy and hardness with build parameters and wall height in directed-energy-deposited 316L steel

Cited by 11 publications

References 38 publications

Calibrated Closed-Loop Control to Reduce the Effect of Geometry on Mechanical Behaviour in Directed Energy Deposition

Calibrated Closed-Loop Control to Reduce the Effect of Geometry on Mechanical Behaviour in Directed Energy Deposition

Multi-Faceted Monitoring of Powder Flow Rate Variability in Directed Energy Deposition

Controlling grain structure in metallic additive manufacturing using a simple, inexpensive process control system

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