Attempting to Develop the World’s Most Cost-Effective Metal 3D Printing Technology Through Industrial Adoption of a High-Temperature Electro-Magnetic Nozzle for 3D Printing and Computer Numerical Control Integration

Michael Kesler; Michael Thompson; Max Neveau; Adrian Sabau; Wenjun Ge; Jason Jones

doi:10.2172/2997793

Attempting to Develop the World’s Most Cost-Effective Metal 3D Printing Technology Through Industrial Adoption of a High-Temperature Electro-Magnetic Nozzle for 3D Printing and Computer Numerical Control Integration

Michael Kesler
, Michael Thompson
, Max Neveau
, Adrian Sabau
, Wenjun Ge
, Jason Jones

Research output: Other contribution › Technical Report

Abstract

This project aimed to make a practical system capable of sustained metal deposition in air engineered with industrial integration and controls. The Al-Ce wire feedstock was tailored with appropriate deposition and solidification properties for direct reactive interface printing (DRIP), and the goal was to integrate onto a Hybrid Manufacturing Technologies system for producing test parts without a controlled environment.

Original language	English
Place of Publication	United States
DOIs	https://doi.org/10.2172/2997793
State	Published - 2025

Keywords

99 GENERAL AND MISCELLANEOUS
Al-Ce wire feedstock, direct reactive interface printing (DRIP), hybrid manufacturing technologies

Access to Document

10.2172/2997793

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abstract = "This project aimed to make a practical system capable of sustained metal deposition in air engineered with industrial integration and controls. The Al-Ce wire feedstock was tailored with appropriate deposition and solidification properties for direct reactive interface printing (DRIP), and the goal was to integrate onto a Hybrid Manufacturing Technologies system for producing test parts without a controlled environment.",

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AU - Sabau, Adrian

AU - Ge, Wenjun

AU - Jones, Jason

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AB - This project aimed to make a practical system capable of sustained metal deposition in air engineered with industrial integration and controls. The Al-Ce wire feedstock was tailored with appropriate deposition and solidification properties for direct reactive interface printing (DRIP), and the goal was to integrate onto a Hybrid Manufacturing Technologies system for producing test parts without a controlled environment.

KW - 99 GENERAL AND MISCELLANEOUS

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