Binder jetting (BJT) is a powder bed based additive manufacturing (AM) process where the interaction of inkjetted droplets of a binder and particles in the powder bed create 3D geometries in a layerwise fashion. The fabricated green parts are usually thermally post-processed for densification and strengthening. BJT holds distinct advantages over other AM processes as it can fabricate parts with virtually any materials (metals, ceramics, and polymers) in a fast and cost-effective way, while achieving isotropic material properties in the parts. However, broad adoption of this process for production is still lagging, partially due to the lack of repeatable part quality, which largely stems from the limited understanding of the process physics, namely binder-powder (B/P) interaction. To bridge this knowledge gap, it is necessary to understand the implications of B/P interaction on process-structure-property relationships and discover ways to achieve new functionalities for enhanced properties. Thus, this research is broadly focused in establishing understanding in (i) binder-powder interaction and (ii) the impact of binder on part densification.
Prior studies have focused on the effects of powder interaction with micro/meso-scale binder droplets, despite commercial BJT systems featuring picoliter-scale droplets. These studies have explored the effects of B/P interaction on printed primitive formation, but it's implication on final part properties have not been studied. In this work, the effects of particle size distribution and droplet size variation on final part properties are explored. Additionally, the effects of B/P interaction on accuracy and the resolution of the printed parts are investigated.
Densification of parts is a primary focus of many BJT studies as it dictates the final part properties and is influenced by factors from both the printing process and post-processing treatments. Binder plays an integral role in the shaping of parts and maintaining part integrity until densification through sintering. Prior studies on the effects of binder content on densification are inclusive. In this work, a new approach termed as "shell printing" is introduced to vary the binder content in the parts. The process-structure-properties influenced by this approach are investigated. It was found that binder hinders densification, and through the selective variation of binder content throughout the part volume, this new approach is introduced as a means for enhancing part properties.
Finally, the insights from the impact of binder on densification are leveraged to create an anti-counterfeiting tagging strategy by controlling the pores and grain microstructures inside a part. In this novel approach, binder concentration is controlled in a manner that the stochastically formed pores are clustered to create a designed domain that represents a secret 'tag' within the part volume. The created tagging domains, and the feature resolvability of this approach are investigated through metallographic characterization and non-destructively evaluated through micro-computed tomography. / Doctor of Philosophy / Binder jetting (BJT) is an additive manufacturing (AM) process to create 3D geometries from powder particles. Liquid droplets of binder from an inkjet printhead are jetted on a bed of packed powders, binding the particles. The as-printed parts, known as green parts, are generally fragile and require thermal post-processing (through sintering) for densification and strengthening. BJT holds distinct advantages over other AM processes as it can fabricate parts with virtually any powdered materials (metals, ceramics, and polymers) in a fast and cost-effective way. However, broad adoption of this process for production is still lagging, partially due to the lack of repeatable part quality, which largely stems from the limited understanding of the process physics, namely binder-powder (B/P) interaction. In this study the implications of B/P interaction on part quality (e.g., density, strength) and dimensional accuracy are studied. Additionally, the impact of binder on sintering densification is studied. Specifically, the effects of varying amount of binder on sintered part density, strength and internal pore and grain microstructures are empirically investigated. Finally, a novel anti-counterfeiting method for BJT printed parts is introduced based on the insights gained from the study of the impact of binder on densification. Through control over binder placement throughout the part, porous regions can be generated selectively throughout the part volume, which can be detected through x-ray computed tomography. Overall, an improved understanding of BJT processing conditions is achieved through this research, which can guide future designers to fabricate BJT parts with enhanced part properties and functionality.
Identifer | oai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/113551 |
Date | 27 January 2023 |
Creators | Rahman, Kazi Moshiur |
Contributors | Mechanical Engineering, Williams, Christopher Bryant, Druschitz, Alan P., Raeymaekers, Bart, West, Robert L. |
Publisher | Virginia Tech |
Source Sets | Virginia Tech Theses and Dissertation |
Language | English |
Detected Language | English |
Type | Dissertation |
Format | ETD, application/pdf |
Rights | In Copyright, http://rightsstatements.org/vocab/InC/1.0/ |
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