TY - GEN
T1 - ROLL-TO-ROLL MANUFACTURING OF BIOMASS MATERIAL FOR SUSTAINABLE THERMAL INSULATION APPLICATION
AU - Liang, Licheng
AU - Guo, Zipeng
AU - Chivate, Aditya
AU - Armstrong, Jason
AU - Zhou, Chi
N1 - Publisher Copyright:
Copyright © 2025 by ASME.
PY - 2025
Y1 - 2025
N2 - Environmental pollution and increased greenhouse gas (GHG) emissions due to reliance on fossil fuels-based products are becoming major causes to global warming. Transitioning to renewable resources such as biomass offers a solution to reduce GHG emissions. Biomass is a renewable, biodegradable resource derived from agricultural residues and wastes, with significant potential as an environmentally friendly feedstock for advanced manufacturing. Their unique properties, such as low thermal conductivity and low density, make them valuable for a wide range of applications, especially in building insulation. In this work, we utilize additive manufacturing (AM) to produce biomass-based insulation panels directly from wheat straw fibers, aiming to transform agricultural wastes into sustainable building materials. Despite the promising benefits, AM faces challenges in scalability and efficiency, especially for industry-scale production. This study addresses these challenges by developing a roll-to-roll printing system with an optimized slot-die nozzle design to increase process throughput. Traditional 3D printing, such as direct ink writing (DIW), typically employs a nozzle with a circular outlet, requiring material deposition along a serial path for each layer. This approach is inefficient for meeting the high throughput demands of producing large-scale insulation panels. To address these limitations, we investigate various nozzle geometries and ultimately optimize the nozzle to a slot-die shape, which improves both material deposition uniformity and printing efficiency. Additionally, we implemented a multi-nozzle configuration to enable simultaneous material deposition, significantly enhancing throughput and ensuring more consistent material deposition compared to a single nozzle system. The manifold design based on a multi-level splitter structure further supports multi-nozzle configuration by ensuring uniform material flow between the nozzles and reducing flow inconsistencies. Through iterative adjustments to both nozzle geometry and manifold alignment, we achieve an optimized balance between process efficiency and product accuracy. This approach demonstrates a sustainable pathway to transform agricultural waste into valuable environmentally friendly building materials.
AB - Environmental pollution and increased greenhouse gas (GHG) emissions due to reliance on fossil fuels-based products are becoming major causes to global warming. Transitioning to renewable resources such as biomass offers a solution to reduce GHG emissions. Biomass is a renewable, biodegradable resource derived from agricultural residues and wastes, with significant potential as an environmentally friendly feedstock for advanced manufacturing. Their unique properties, such as low thermal conductivity and low density, make them valuable for a wide range of applications, especially in building insulation. In this work, we utilize additive manufacturing (AM) to produce biomass-based insulation panels directly from wheat straw fibers, aiming to transform agricultural wastes into sustainable building materials. Despite the promising benefits, AM faces challenges in scalability and efficiency, especially for industry-scale production. This study addresses these challenges by developing a roll-to-roll printing system with an optimized slot-die nozzle design to increase process throughput. Traditional 3D printing, such as direct ink writing (DIW), typically employs a nozzle with a circular outlet, requiring material deposition along a serial path for each layer. This approach is inefficient for meeting the high throughput demands of producing large-scale insulation panels. To address these limitations, we investigate various nozzle geometries and ultimately optimize the nozzle to a slot-die shape, which improves both material deposition uniformity and printing efficiency. Additionally, we implemented a multi-nozzle configuration to enable simultaneous material deposition, significantly enhancing throughput and ensuring more consistent material deposition compared to a single nozzle system. The manifold design based on a multi-level splitter structure further supports multi-nozzle configuration by ensuring uniform material flow between the nozzles and reducing flow inconsistencies. Through iterative adjustments to both nozzle geometry and manifold alignment, we achieve an optimized balance between process efficiency and product accuracy. This approach demonstrates a sustainable pathway to transform agricultural waste into valuable environmentally friendly building materials.
KW - Biomass material
KW - Building application
KW - Roll-to-roll manufacturing
KW - Thermal insulation
UR - https://www.scopus.com/pages/publications/105019487159
U2 - 10.1115/MSEC2025-155851
DO - 10.1115/MSEC2025-155851
M3 - Conference contribution
AN - SCOPUS:105019487159
T3 - Proceedings of ASME 2025 20th International Manufacturing Science and Engineering Conference, MSEC 2025
BT - Functional Devices/Bioinspired Structures; Sustainability; Semiconductor Manufacturing; Surface Engineering; Clean Energy and E-Mobility Manufacturing; Machining and Deformation Processes; Welding and Joining Processes of Advanced Materials and Structures; Equipment Design, Control and Automation; Human Integration to Smart Manufacturing Systems; Thin Films and Coatings; Meso, Micro, Nano Subtractive and Formative Manufacturing; Explainable AI for Knowledge Discovery
PB - American Society of Mechanical Engineers (ASME)
T2 - ASME 2025 20th International Manufacturing Science and Engineering Conference, MSEC 2025
Y2 - 23 June 2025 through 27 June 2025
ER -