Fused Deposition Modelling (FDM) technology allows to choose a large variety of materials and it is widely used by companies and individuals nowadays. The cost effectiveness of rapid prototyping is achievable via FDM, that makes this technology useful for research and innovation. The application of 3D printing to aid production is the most common approach. Moreover, the use of 3D printing in prototypes result in a waste of material since no reuse is considered. In the following manuscript, this technology is applied to mould fabrication by achieving a low surface roughness at a modest cost compared to conventional manufacturing methods. Moreover, the possibility to use a combination of thermoplastic materials is analysed by examination of the CAD model optimized for Additive Manufacturing (AM) from scratch and was verified using metrology tools. Several moulds were finally built and applied to the specific case study of carbon fibre laminated components. This manuscript aims to analyse the manufacturing process by comparing the mould surface geometry before and after the smoothing process. The achieved tolerance between the produced moulds is ±0.05 mm that ensures the repeatability of the process from an industrial point of view; whilst the deviation between CAD and mould is ±0.2 mm. To combine an accurate FDM process together with chemical smoothing proved to be a powerful strategy to produce high quality components that can be inserted in the production process by means of traditional manufacturing techniques. This will aid to reduce the cost of standard manufacturing for low production batches and prototypes of carbon fibre composites.

Patrich Ferretti, Gian Maria Santi, Christian Leon-Cardenas, Elena Fusari, Mattia Cristofori, Alfredo Liverani (2022). Production readiness assessment of low cost, multi-material, polymeric 3D printed moulds. HELIYON, 8(10), 1-13 [10.1016/j.heliyon.2022.e11136].

Production readiness assessment of low cost, multi-material, polymeric 3D printed moulds

Patrich Ferretti
;
Gian Maria Santi;Christian Leon-Cardenas
;
Alfredo Liverani
2022

Abstract

Fused Deposition Modelling (FDM) technology allows to choose a large variety of materials and it is widely used by companies and individuals nowadays. The cost effectiveness of rapid prototyping is achievable via FDM, that makes this technology useful for research and innovation. The application of 3D printing to aid production is the most common approach. Moreover, the use of 3D printing in prototypes result in a waste of material since no reuse is considered. In the following manuscript, this technology is applied to mould fabrication by achieving a low surface roughness at a modest cost compared to conventional manufacturing methods. Moreover, the possibility to use a combination of thermoplastic materials is analysed by examination of the CAD model optimized for Additive Manufacturing (AM) from scratch and was verified using metrology tools. Several moulds were finally built and applied to the specific case study of carbon fibre laminated components. This manuscript aims to analyse the manufacturing process by comparing the mould surface geometry before and after the smoothing process. The achieved tolerance between the produced moulds is ±0.05 mm that ensures the repeatability of the process from an industrial point of view; whilst the deviation between CAD and mould is ±0.2 mm. To combine an accurate FDM process together with chemical smoothing proved to be a powerful strategy to produce high quality components that can be inserted in the production process by means of traditional manufacturing techniques. This will aid to reduce the cost of standard manufacturing for low production batches and prototypes of carbon fibre composites.
2022
Patrich Ferretti, Gian Maria Santi, Christian Leon-Cardenas, Elena Fusari, Mattia Cristofori, Alfredo Liverani (2022). Production readiness assessment of low cost, multi-material, polymeric 3D printed moulds. HELIYON, 8(10), 1-13 [10.1016/j.heliyon.2022.e11136].
Patrich Ferretti; Gian Maria Santi; Christian Leon-Cardenas; Elena Fusari; Mattia Cristofori; Alfredo Liverani
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/919388
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