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Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

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Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition. / Pinkerton, A. J.; Li, L.
Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping. ed. / P. J. Bartolo; G. Mitchell; A. Mateus; F. Batista; J. Vasco; M. Correia; N. Andre; P. Lima; P. Novo; P. Custodio; P. Martinho. Leiria: Escola Superior Tecnologia Gestao Leiria, 2003. p. 224-231.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Pinkerton, AJ & Li, L 2003, Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition. in PJ Bartolo, G Mitchell, A Mateus, F Batista, J Vasco, M Correia, N Andre, P Lima, P Novo, P Custodio & P Martinho (eds), Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping. Escola Superior Tecnologia Gestao Leiria, Leiria, pp. 224-231, 1st International Conference on Advanced Research in Virtual and Rapid Prototyping, Leiria, 1/10/03.

APA

Pinkerton, A. J., & Li, L. (2003). Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition. In P. J. Bartolo, G. Mitchell, A. Mateus, F. Batista, J. Vasco, M. Correia, N. Andre, P. Lima, P. Novo, P. Custodio, & P. Martinho (Eds.), Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping (pp. 224-231). Escola Superior Tecnologia Gestao Leiria.

Vancouver

Pinkerton AJ, Li L. Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition. In Bartolo PJ, Mitchell G, Mateus A, Batista F, Vasco J, Correia M, Andre N, Lima P, Novo P, Custodio P, Martinho P, editors, Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping. Leiria: Escola Superior Tecnologia Gestao Leiria. 2003. p. 224-231

Author

Pinkerton, A. J. ; Li, L. / Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition. Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping. editor / P. J. Bartolo ; G. Mitchell ; A. Mateus ; F. Batista ; J. Vasco ; M. Correia ; N. Andre ; P. Lima ; P. Novo ; P. Custodio ; P. Martinho. Leiria : Escola Superior Tecnologia Gestao Leiria, 2003. pp. 224-231

Bibtex

@inproceedings{cb1f551ce2494a0b8471578ecd83459b,
title = "Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition",
abstract = "Direct metal deposition by laser is a flexible, single-stage additive manufacturing process that has significant potential impact in rapid prototyping, tooling and small volume manufacturing applications. The process requires either pneumatically conveyed metal powder or wire to be delivered to a melt pool, created by a defocused laser beam. Therefore, the size of the melt pool and the temperature distributions around it are critical in determining process characteristics such as deposition rate. In this paper, the effect that changes in the distance between the deposition head and the melt pool has on these factors, as a part is built-up using a coaxial powder feeding system, is considered via an analytical model. It demonstrates the effect of adjusting the melt pool standoff in different ways on melt pool and powder flow characteristics as a wall grows, and hence allows the effect on build rate to be predicted. Its validity is verified by comparison with a series of 316L stainless steel walls, built using different standoff adjustment methods. The model is found to be able to explain the dimensional characteristics found.",
author = "Pinkerton, {A. J.} and L. Li",
year = "2003",
language = "English",
pages = "224--231",
editor = "Bartolo, {P. J.} and G. Mitchell and A. Mateus and F. Batista and J. Vasco and M. Correia and N. Andre and P. Lima and P. Novo and P. Custodio and P. Martinho",
booktitle = "Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping",
publisher = "Escola Superior Tecnologia Gestao Leiria",
note = "1st International Conference on Advanced Research in Virtual and Rapid Prototyping ; Conference date: 01-10-2003 Through 04-10-2003",

}

RIS

TY - GEN

T1 - Modelling the temperature effects of melt pool position and wall height in additive manufacturing by direct laser deposition

AU - Pinkerton, A. J.

AU - Li, L.

PY - 2003

Y1 - 2003

N2 - Direct metal deposition by laser is a flexible, single-stage additive manufacturing process that has significant potential impact in rapid prototyping, tooling and small volume manufacturing applications. The process requires either pneumatically conveyed metal powder or wire to be delivered to a melt pool, created by a defocused laser beam. Therefore, the size of the melt pool and the temperature distributions around it are critical in determining process characteristics such as deposition rate. In this paper, the effect that changes in the distance between the deposition head and the melt pool has on these factors, as a part is built-up using a coaxial powder feeding system, is considered via an analytical model. It demonstrates the effect of adjusting the melt pool standoff in different ways on melt pool and powder flow characteristics as a wall grows, and hence allows the effect on build rate to be predicted. Its validity is verified by comparison with a series of 316L stainless steel walls, built using different standoff adjustment methods. The model is found to be able to explain the dimensional characteristics found.

AB - Direct metal deposition by laser is a flexible, single-stage additive manufacturing process that has significant potential impact in rapid prototyping, tooling and small volume manufacturing applications. The process requires either pneumatically conveyed metal powder or wire to be delivered to a melt pool, created by a defocused laser beam. Therefore, the size of the melt pool and the temperature distributions around it are critical in determining process characteristics such as deposition rate. In this paper, the effect that changes in the distance between the deposition head and the melt pool has on these factors, as a part is built-up using a coaxial powder feeding system, is considered via an analytical model. It demonstrates the effect of adjusting the melt pool standoff in different ways on melt pool and powder flow characteristics as a wall grows, and hence allows the effect on build rate to be predicted. Its validity is verified by comparison with a series of 316L stainless steel walls, built using different standoff adjustment methods. The model is found to be able to explain the dimensional characteristics found.

M3 - Conference contribution/Paper

SP - 224

EP - 231

BT - Proceedings of the 1st International Conference on Advanced Research in Virtual and Rapid Prototyping

A2 - Bartolo, P. J.

A2 - Mitchell, G.

A2 - Mateus, A.

A2 - Batista, F.

A2 - Vasco, J.

A2 - Correia, M.

A2 - Andre, N.

A2 - Lima, P.

A2 - Novo, P.

A2 - Custodio, P.

A2 - Martinho, P.

PB - Escola Superior Tecnologia Gestao Leiria

CY - Leiria

T2 - 1st International Conference on Advanced Research in Virtual and Rapid Prototyping

Y2 - 1 October 2003 through 4 October 2003

ER -