Using single pulses in powder-blown directed energy deposition to fabricate high-aspect-ratio metal pins

Wessel W. Wits; Shenliang Yang; Jos Vroon; Scholte J.L. Bremer

doi:10.1016/j.cirp.2026.04.001

Using single pulses in powder-blown directed energy deposition to fabricate high-aspect-ratio metal pins

Wessel W. Wits^*
, Shenliang Yang
, Jos Vroon
, Scholte J.L. Bremer

^*Corresponding author for this work

Robotics and Mechatronics

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

This study investigates the fabrication of high-aspect-ratio metal pins using powder-blown directed energy deposition. Pins are deposited by consecutive laser pulses using titanium alloy Ti6Al4V as feedstock material. A physics-integrated experimental-analytical-numerical framework is developed to predict pin geometry, pin growth and thermal history during fabrication. The framework combines experimental in-situ temperature measurements, an analytical geometry model, and a finite element thermal model for melt pool lifetime predictions. Results show good agreement between model predictions and experimental observations, enabling controlled constant-diameter vertical pin growth with optimised process parameters, which is crucial for applications such as hybrid metal-composite joining and structural repair.

Original language	English
Journal	CIRP Annals
DOIs	https://doi.org/10.1016/j.cirp.2026.04.001
Publication status	E-pub ahead of print/First online - 6 May 2026

Keywords

UT-Hybrid-D
Directed energy deposition (DED)
High-aspect-ratio metal pins
Additive manufacturing (AM)

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title = "Using single pulses in powder-blown directed energy deposition to fabricate high-aspect-ratio metal pins",

abstract = "This study investigates the fabrication of high-aspect-ratio metal pins using powder-blown directed energy deposition. Pins are deposited by consecutive laser pulses using titanium alloy Ti6Al4V as feedstock material. A physics-integrated experimental-analytical-numerical framework is developed to predict pin geometry, pin growth and thermal history during fabrication. The framework combines experimental in-situ temperature measurements, an analytical geometry model, and a finite element thermal model for melt pool lifetime predictions. Results show good agreement between model predictions and experimental observations, enabling controlled constant-diameter vertical pin growth with optimised process parameters, which is crucial for applications such as hybrid metal-composite joining and structural repair.",

keywords = "UT-Hybrid-D, Directed energy deposition (DED), High-aspect-ratio metal pins, Additive manufacturing (AM)",

author = "Wits, \{Wessel W.\} and Shenliang Yang and Jos Vroon and Bremer, \{Scholte J.L.\}",

note = "Publisher Copyright: {\textcopyright} 2026 The Author(s). Published by Elsevier Ltd on behalf of CIRP. This is an open access article under the CC BY license. http://creativecommons.org/licenses/by/4.0/",

year = "2026",

month = may,

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doi = "10.1016/j.cirp.2026.04.001",

language = "English",

journal = "CIRP Annals",

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T1 - Using single pulses in powder-blown directed energy deposition to fabricate high-aspect-ratio metal pins

AU - Wits, Wessel W.

AU - Yang, Shenliang

AU - Vroon, Jos

AU - Bremer, Scholte J.L.

PY - 2026/5/6

Y1 - 2026/5/6

N2 - This study investigates the fabrication of high-aspect-ratio metal pins using powder-blown directed energy deposition. Pins are deposited by consecutive laser pulses using titanium alloy Ti6Al4V as feedstock material. A physics-integrated experimental-analytical-numerical framework is developed to predict pin geometry, pin growth and thermal history during fabrication. The framework combines experimental in-situ temperature measurements, an analytical geometry model, and a finite element thermal model for melt pool lifetime predictions. Results show good agreement between model predictions and experimental observations, enabling controlled constant-diameter vertical pin growth with optimised process parameters, which is crucial for applications such as hybrid metal-composite joining and structural repair.

AB - This study investigates the fabrication of high-aspect-ratio metal pins using powder-blown directed energy deposition. Pins are deposited by consecutive laser pulses using titanium alloy Ti6Al4V as feedstock material. A physics-integrated experimental-analytical-numerical framework is developed to predict pin geometry, pin growth and thermal history during fabrication. The framework combines experimental in-situ temperature measurements, an analytical geometry model, and a finite element thermal model for melt pool lifetime predictions. Results show good agreement between model predictions and experimental observations, enabling controlled constant-diameter vertical pin growth with optimised process parameters, which is crucial for applications such as hybrid metal-composite joining and structural repair.

KW - UT-Hybrid-D

KW - Directed energy deposition (DED)

KW - High-aspect-ratio metal pins

KW - Additive manufacturing (AM)

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U2 - 10.1016/j.cirp.2026.04.001

DO - 10.1016/j.cirp.2026.04.001

M3 - Article

AN - SCOPUS:105037658992

SN - 0007-8506

JO - CIRP Annals

JF - CIRP Annals

ER -

Using single pulses in powder-blown directed energy deposition to fabricate high-aspect-ratio metal pins

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Keywords

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