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Silicone 3D printing holds a significant potential in soft robotics, stretchable electronics, and custom medical devices. However, challenges such as inconsistent material deposition continue to limit printing precision. This study presents a reduced-order numerical model integrating material rheology, process parameters and nozzle geometry to optimize silicone extrusion. A support vector regression algorithm fine-tunes printing parameters to generate an inlet pressure profile that minimizes over- and under-extrusion and ensures precise layer contouring. Full three-dimensional simulations of non-Newtonian silicone deposition coupled with experimental validation confirm the model's accuracy in 3D printing a 90-degree rounded corner shape. The proposed approach yields more stable printing paths and reduces layer width variability to 4.21%, compared to 15.02% obtained with constant inlet pressure. Finally, the proposed model is applied to fabricate wavy and multi-strand paths, demonstrating enhanced accuracy and consistency.

Silicone 3D printing: Experimental validation of a reduced-order numerical model for optimal layer deposition / Pricci, Alessio; Percoco, Gianluca. - 57:(2025), pp. 180-189. (Intervento presentato al convegno 17th Italian Manufacturing Association Conference, AITeM 2025 tenutosi a Bari nel 2025) [10.21741/9781644903735-21].

Silicone 3D printing: Experimental validation of a reduced-order numerical model for optimal layer deposition

Pricci, Alessio;Percoco, Gianluca

2025

Abstract

Silicone 3D printing holds a significant potential in soft robotics, stretchable electronics, and custom medical devices. However, challenges such as inconsistent material deposition continue to limit printing precision. This study presents a reduced-order numerical model integrating material rheology, process parameters and nozzle geometry to optimize silicone extrusion. A support vector regression algorithm fine-tunes printing parameters to generate an inlet pressure profile that minimizes over- and under-extrusion and ensures precise layer contouring. Full three-dimensional simulations of non-Newtonian silicone deposition coupled with experimental validation confirm the model's accuracy in 3D printing a 90-degree rounded corner shape. The proposed approach yields more stable printing paths and reduces layer width variability to 4.21%, compared to 15.02% obtained with constant inlet pressure. Finally, the proposed model is applied to fabricate wavy and multi-strand paths, demonstrating enhanced accuracy and consistency.

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	Anno
	
				2025
			
	Titolo del convegno
	
				17th Italian Manufacturing Association Conference, AITeM 2025
			
	Codice DOI
	
				https://dx.doi.org/10.21741/9781644903735-21
			
	Citazione
	
				Silicone 3D printing: Experimental validation of a reduced-order numerical model for optimal layer deposition / Pricci, Alessio; Percoco, Gianluca. - 57:(2025), pp. 180-189. (Intervento presentato al  convegno 17th Italian Manufacturing Association Conference, AITeM 2025 tenutosi a Bari nel 2025) [10.21741/9781644903735-21].
			
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				4.1 Contributo in Atti di convegno

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11589/292787

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