What question did this study set out to answer?

This research aims to enhance the fabrication process of high-aspect-ratio metal pins using an integrated modeling approach.

May 8, 2026Open Access

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

Key Points

This research aims to enhance the fabrication process of high-aspect-ratio metal pins using an integrated modeling approach.
Developed a physics-integrated experimental-analytical-numerical framework.
Utilized titanium alloy Ti6Al4V as feedstock material for pin deposition.
Combined experimental temperature measurements, analytical models, and finite element analysis for predictions.
Model predictions align well with experimental data, confirming controlled vertical pin growth.
Achieved constant-diameter pin growth with optimized parameters.
Outcomes are essential for applications in hybrid metal-composite joining and repairs.

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.

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

Key Points

Abstract

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