Conference proceeding
Characterization of Interfaces Between Layers of Differently Sized Particles in Pressure-Assisted Binder Jetting
Volume 1: Smart Additive Manufacturing; Multi-Material Processing in AM; Advances in Metal AM Processes; In Situ Monitoring, Non-Destructive Evaluation, and Qualification for AM; Advances in Manufacturing and Processing of Polymers and Composites; Laser-Based Advanced Manufacturing and Material Processing; Smart, Innovative, and Low-Cost Tooling Systems for Advanced Materials Manufacturing; Bio-Manufacturing of Engineered Living Materials
ASME 2025 20th International Manufacturing Science and Engineering Conference, Greenville, South Carolina, USA, Jun. 23 - 27, 2025
06/23/2025
DOI: 10.1115/MSEC2025-155934
Abstract
Abstract
This study aims to quantify the interfaces between adjacent layers of differently sized particles fabricated using a pressure-assisted binder jet additive manufacturing (AM) process. Sugar particles are used as model material, which has been widely studied as a simulant for energetic materials. A particle coloring approach was employed to visualize the intermixing zone between layers, enabling quantification of key interface characteristics, including intermixing thickness and porosity. By changing the binder concentration in the adjacent layers, the profile of the interface varies, e.g., from a narrow, straight, horizontal band to a thick, gradient, jagged region. A low binder concentration in fine particles resulted in brittleness and more resistance to particle rearrangement, restricting large particle penetration into the fine particle layer under pressing and leading to a thinner, sharper intermixing zone. In contrast, a high binder concentration in fine particles yields a ductile, deformable microstructure, promoting fine particle rearrangement, large particle penetration, and a thicker intermixing zone. Tensile tests, in situ optical imaging, and digital imaging correlation (DIC) were conducted to analyze the mechanical behavior of the interfaces. Crack initiation and propagation along the interface have not been observed, suggesting that the intermixing of particles at the interface not only preserved the mechanical performance but also enhanced it beyond that of the neighboring layers. This research provides insights into the interaction between differently sized particles being pressed into each other and the effect of binder concentration on interfacial characteristics in pressure-assisted binder jetting, advancing understanding of microstructures and properties in additively manufactured multi-material composites.
Details
- Title: Subtitle
- Characterization of Interfaces Between Layers of Differently Sized Particles in Pressure-Assisted Binder Jetting
- Creators
- Nazanin TabatabaeiXuan Song
- Resource Type
- Conference proceeding
- Publication Details
- Volume 1: Smart Additive Manufacturing; Multi-Material Processing in AM; Advances in Metal AM Processes; In Situ Monitoring, Non-Destructive Evaluation, and Qualification for AM; Advances in Manufacturing and Processing of Polymers and Composites; Laser-Based Advanced Manufacturing and Material Processing; Smart, Innovative, and Low-Cost Tooling Systems for Advanced Materials Manufacturing; Bio-Manufacturing of Engineered Living Materials
- Conference
- ASME 2025 20th International Manufacturing Science and Engineering Conference, Greenville, South Carolina, USA, Jun. 23 - 27, 2025
- DOI
- 10.1115/MSEC2025-155934
- Publisher
- American Society of Mechanical Engineers
- Language
- English
- Date published
- 06/23/2025
- Academic Unit
- Industrial and Systems Engineering; Injury Prevention Research Center; Mechanical Engineering
- Record Identifier
- 9984966801602771
Metrics
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