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1. Development of Wire Delivery Tool With Desktop 3-D Printer for Multifunctional Additive Manufacturing

   https://doi.org/10.1115/MSEC2024-125414  

   Billah, Kazi_Md_Masum; Rathod, Neel_Ashwinbhai; Gonzalez, Mario_Barron; Gleasman, Jeffrey; Lopez, Ruben_Alan; Torres, Kristian (June 2024, American Society of Mechanical Engineers)

   Abstract Additive manufacturing (AM), also known as 3D printing, has significantly advanced in recent years, especially with the introduction of multifunctional 3D-printed parts. AM fabricated monolith has multiple material capabilities, thus various functionalities are well-perceived by the manufacturing communities. As an example, a traditional fused filament fabrication (FFF) 3D printer fabricates multi-material thermoplastic parts using a dual extrusion system to increase the functionality of the part including variable stiffening and gradient structures. In addition to the multiple thermoplastic feedstocks in a dual extrusion system, multifunctional AM can be achieved by embedding electronics or reinforcing fibers within the fabricated thermoplastic parts, which significantly impacts the rapid prototyping of hybrid components in manufacturing industries. State-of-the-art techniques such as coextrusion systems, ultrasonic welding tools, and thermal embedding tools have been implemented to automate the process of embedding conductive material within the 3D-printed thermoplastic substrate. The goal of this tool development effort is to embed wires within 3D 3D-printed plastic substrate. This research consisted of developing a wire embedding tool that can be integrated into an FFF desktop 3D printer to deposit conductive as well as resistive wires within the 3D-printed thermoplastic substrate. By realizing the challenges for discrete materials interaction at the interface such as nichrome wires and Acrylonitrile Butadiene Styrene (ABS) plastics and polylactic acid (PLA), the goal of this tool was to immerse wire within ABS and PLA substrate using transient swelling mechanisms under non-polar solvent. A proof-of-concept test stands with a wire feed system and the embedding wheel was first designed and manufactured using 3D printing to examine if a traditional roller-guided system, primarily used for plastic extrusion, would be sufficient for wire extrusion. The development of the integrated wire embedding tool was initiated based on the success of the proof-of-concept wire extrusion system. The design of the integrated wire embedding tool consisted of three sub-assemblies: wire delivery assembly, wire shearing assembly, and swivel assembly. The wire delivery assembly is responsible for feeding the wire towards the thermoplastic using the filament delivery system seen within FFF printers. For the wire shearing mechanism, a cutting Tungsten carbide blade in conjunction with a Nema-17 external stepper motor was used to shear the wire. For the wire embedding assembly, a custom swivel mount was fabricated with a bearing housing for a ball bearing that allowed for a 360-degree motion around the horizontal plane. A wire guide nozzle was placed through the mount to allow for the wire to be fed down into a brass embedding wheel in a tangential manner. Additionally, the solvent reservoir was mounted such that an even layer of solution was dispensed onto the thermoplastic substrate. Through this tool development effort, the aim was to develop technologies that will enable 3D printing of wire-embedded monolith for various applications including a self-heating mold of thermoset-based composite manufacturing as well as smart composites with embedded sensors. 

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2. Systematic Evaluation of Adhesion and Fracture Toughness in Multi-Material Fused Deposition Material Extrusion

   https://doi.org/10.3390/ma17163953  

   Jafor, Md Abu; Sayah, Neshat; Smith, Douglas E; Stano, Gianni; Fleck, Trevor J (August 2024, Materials)

   Material extrusion (MEX) additive manufacturing has successfully fabricated assembly-free structures composed of different materials processed in the same manufacturing cycle. Materials with different mechanical properties can be employed for the fabrication of bio-inspired structures (i.e., stiff materials connected to soft materials), which are appealing for many fields, such as bio-medical and soft robotics. In the present paper, process parameters and 3D printing strategies are presented to improve the interfacial adhesion between carbon fiber-reinforced nylon (CFPA) and thermoplastic polyurethane (TPU), which are extruded in the same manufacturing cycle using a multi-material MEX setup. To achieve our goal, a double cantilever beam (DCB) test was used to evaluate the mode I fracture toughness. The results show that the application of a heating gun (assembled near the nozzle) provides a statistically significant increase in mean fracture toughness energy from 12.3 kJ/m2 to 33.4 kJ/m2. The underlying mechanism driving this finding was further investigated by quantifying porosity at the multi-material interface using an X-ray computed tomography (CT) system, in addition to quantifying thermal history. The results show that using both bead ironing and the hot air gun during the printing process leads to a reduction of 24% in the average void volume fraction. The findings from the DCB test and X-ray CT analysis agree well with the polymer healing theory, in which an increased thermal history led to an increased fracture toughness at the multi-material interface. Moreover, this study considers the thermal history of each printed layer to correlate the measured debonding energy with results obtained using the reptation theory. 

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3. Particle–polymer interactions for 3D printing material design

   https://doi.org/10.1063/5.0179181  

   Mitchell, Kellen; Hua, Weijian; Bandala, Erick; Gaharwar, Akhilesh K; Jin, Yifei (March 2024, Chemical Physics Reviews)

   Embedded ink writing (EIW) and direct ink writing (DIW) constitute the primary strategies for three-dimensional (3D) printing within the realm of material extrusion. These methods enable the rapid fabrication of complex 3D structures, utilizing either yield-stress support baths or self-supporting inks. Both these strategies have been extensively studied across a range of fields, including biomedical, soft robotics, and smart sensors, due to their outstanding print fidelity and compatibility with diverse ink materials. Particle additives capable of forming volume-filling 3D networks are frequently incorporated into polymer solvents. This integration is crucial for engineering the requisite microstructures essential for the formulation of successful support bath and ink materials. The interplay between the particle additives and polymer solvents is critical for achieving rheological tunability in various 3D printing strategies, yet this area has not been systematically reviewed. Therefore, in this critical review, we examined various mechanisms of particle–polymer interactions, the resulting microstructures, and their subsequent impact on mechanical and rheological properties. Overall, this work aims to serve as a foundational guideline for the design of next-generation materials in the field of extrusion additive manufacturing, specifically for EIW and DIW. 

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4. A Review of Non-Powder-Bed Metal Additive Manufacturing: Techniques and Challenges

   https://doi.org/10.3390/ma17194717  

   Xu, Jie; Fei, Yifan; Zhu, Yuanzhe; Yu, Wei; Yao, Donggang; Zhou, Jack G (October 2024, Materials)

   Metal additive manufacturing has significantly evolved since the 1990s, achieving a market valuation of USD 6.36 billion in 2022, with an anticipated compound annual growth rate of 24.2% from 2023 to 2030. While powder-bed-based methods like powder bed fusion and binder jetting dominate the market due to their high accuracy and resolution, they face challenges such as lengthy build times, excessive costs, and safety concerns. Non-powder-bed-based techniques, including direct energy deposition, material extrusion, and sheet lamination, offer advantages such as larger build sizes and lower energy consumption but also encounter issues like residual stress and poor surface finish. The existing reviews of non-powder-bed-based metal additive manufacturing are restricted to one technical branch or one specific material. This survey investigates and analyzes each non-powder-bed-based technique in terms of its manufacturing method, materials, product quality, and summary for easy understanding and comparison. Innovative designs and research status are included. 

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5. Nozzle Pressure Defect Detection in Extrusion-Based Bio 3D Printing Using Video-Based Motion Estimation

   https://doi.org/10.1115/SMASIS2024-140392  

   Rahman, Md Anisur; Khan, Md_Asif Hasan; Kim, Jinki (September 2024, American Society of Mechanical Engineers)

   The emergence of bio-additive manufacturing marks a crucial advancement in the field of biomedical engineering. For successful biomedical applications including bioprinted organ transplants, ensuring the quality of printed structures poses a significant challenge. Among the major challenges encountered in ensuring the structural integrity of bioprinting, nozzle clogging stands out as one of the frequent concerns in the process. It disrupts the uniform distribution of extrusion pressure, leading to the formation of defective structures. This study focused on detecting defects arising from the irregularities in extrusion pressure. To address this concern, a video-based motion estimation technique, which emerged as a novel non-contact and non-destructive technique for assessing bio 3D printed structures, is employed in this research. While other advancements, including contact-based and laser-based approaches, may offer limited performance due to the soft, lightweight, and translucent nature of bioconstructs. In this study, defective and non-defective ear models are additively manufactured by an extrusion-based bioprinter with pneumatic dispensing. Extrusion pressure was strategically controlled to introduce defective bioprints similar to those caused by nozzle malfunctions. The vibration characteristics of the ear structures are captured by a high-speed camera and analyzed using phase-based motion estimation approaches. In addition to ambient excitations from the printing process, acoustic excitations from a subwoofer are employed to assess its impact on print quality. The increase in extrusion pressure, simulating clogged nozzle issues, resulted in significant changes in the vibration characteristics, including shifts in the resonance frequencies. By monitoring these modal property changes, defective bioconstructs could be reliably determined. These findings suggest that the proposed approach could effectively verify the structural integrity of additively manufactured bioconstructs. Implementing this method along with the real time defect detection technique will significantly enhance the structural integrity of additively manufactured bioconstructs and ultimately improve the production of healthy artificial organs, potentially saving countless lives. 

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