SubsidieMeestersStudying Threads Intricately Complex Hydrodynamics
The project aims to explore fluid dynamics in knitting-like patterns to create resilient solid materials, enabling innovative aerial printing methods for diverse applications.
Projectdetails
Introduction
When knitting meets fluid dynamics. Knitting generates fabrics by meticulously guiding yarn into interlocking loops and stitches. Inspired by the legacy of this ancient craft, we propose to study the formation and deformation of complex entangled assemblies “stitched” by the liquid rope coiling instability.
Research Focus
We will study the periodic stitch-like patterns forming when a viscous thread falls and buckles onto a moving substrate, such as the coils created when honey is poured onto toast. Here, we focus on the case of solidifying liquids that “freeze” the patterns formed by these flows into structured solids. In turn, these structures can be leveraged to achieve tunable mechanical properties.
Methodology
This approach is an instability-augmented version of 3D printing where fluid dynamics co-fabricates the parts, e.g., by coiling and layering fused thermoplastic filaments. Despite their singular potential for materials’ design and fabrication, our understanding of these complex flows remains sparse, leaving outstanding scientific questions unanswered. STITCH will fill this gap of knowledge and elucidate the intricate relation between flow, form, and function.
Integration of Techniques
We will integrate rigorous experimentation and modeling techniques to rationalize how our liquid patterns fuse into resilient solid composite materials. This deeper understanding will allow us to tame instabilities in solidifying melts, serving as the foundation for engineering precisely crafted architected solids across length scales.
Impact and Goals
This research has the potential to impact diverse sectors, from tissue engineering to construction. We will leverage our findings to push innovative frontiers in manufacturing with the ambitious and high-risk goal of developing aerial printing methodologies, where one or more drones work together to build from the sky.
Conclusion
Our fundamental work is dedicated to materializing this nascent paradigm, bringing it from the realm of science fiction into concrete reality.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.380.750 |
| Totale projectbegroting | € 2.380.750 |
Tijdlijn
| Startdatum | 1-9-2025 |
| Einddatum | 31-8-2030 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- KATHOLIEKE UNIVERSITEIT LEUVENpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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Jam with the flow: Microgel-based (bio)inks that assemble during printing
Developing microgel-based materials for extrusion-based 3D printing to create stable, heterogeneous scaffolds with precise control over local properties for biomedical applications.
Elasticity, capillarity and imbibition in textiles
The ElCapiTex project aims to characterize and model the behavior of wet non-woven textiles to develop sustainable alternatives to plastics through innovative processes and tailored properties.
Dynamic control of Gaussian morphing structures via embedded fluidic networks
The project aims to create fully controllable shape-morphing materials using hybrid elastic plates with fluid-filled cavities, enabling precise programming of shape, mechanics, and deformation dynamics for biomedical applications.
Unravelling unsteady fluid flows in porous media with 3D X-ray micro-velocimetry
FLOWSCOPY aims to revolutionize the understanding of fluid flows in opaque porous materials by developing a fast 3D X-ray imaging method to measure complex flow dynamics at micro and macro scales.
Fluidic Shaping of Optical Components on Earth and in Space
The project aims to develop Fluidic Shaping for rapid, high-precision optical component fabrication using liquid interfaces, enhancing accessibility in various fields including space exploration and astronomy.
Vergelijkbare projecten uit andere regelingen
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|---|---|---|---|---|
FlexiForm - Structurally and materially informed design and fabrication strategies for knitted textile formworks for concrete structuresThe FlexiForm project aims to revolutionize construction by reducing material use and carbon footprint through innovative design and lightweight 3D knitted textiles, promoting sustainability and efficiency. | EIC Pathfinder | € 1.322.281 | 2024 | Details |
K.N.I.T.T.: Knitwear Next-level Interactive Textile TechnologyHet project van Knitwear Lab B.V. en Raverko B.V. ontwikkelt een 3D-simuleringstool voor duurzame textielproductie, gericht op co-creatie en de overgang naar digitale productpaspoorten. | Mkb-innovati... | € 151.428 | 2023 | Details |
FlexiForm - Structurally and materially informed design and fabrication strategies for knitted textile formworks for concrete structures
The FlexiForm project aims to revolutionize construction by reducing material use and carbon footprint through innovative design and lightweight 3D knitted textiles, promoting sustainability and efficiency.
K.N.I.T.T.: Knitwear Next-level Interactive Textile Technology
Het project van Knitwear Lab B.V. en Raverko B.V. ontwikkelt een 3D-simuleringstool voor duurzame textielproductie, gericht op co-creatie en de overgang naar digitale productpaspoorten.