Additive Manufacturing in Underwater Applications

Korniejenko, Kinga; Gądek, Szymon; Dynowski, Piotr; Tran, Doan Hung; Rudziewicz, Magdalena; Pose, Sebastian; Grab, Thomas

doi:10.3390/app14041346

Applied Sciences

2024

DOI: 10.3390/app14041346

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Additive Manufacturing in Underwater Applications

Kinga Korniejenko,

Szymon Gądek,

Piotr Dynowski

et al.

Abstract: Additive manufacturing (AM), commonly named 3D printing, is a promising technology for many applications. It is the most viable option for widespread use in automated construction processes, especially for harsh environments such as underwater. Some contemporary applications of this technology have been tested in underwater environments, but there are still a number of problems to be solved. This study focuses on the current development of 3D printing technology for underwater applications, including the requi… Show more

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Cited by 4 publications

References 127 publications

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Gupta,

Sachdeva,

Kumar

2024

J. of Materi Eng and Perform

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Evaluating the Mechanical Characteristics of Graphene Nanoparticle-Infused Polyurethane Coating on Low-Density Polylactic Acid Part

Gupta,

Sachdeva,

Kumar

2024

J. of Materi Eng and Perform

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Using a Model Created Using a 3D Printer to Mould a Grey Cast Iron Casting

Ráž,

Chval,

Kořínek

2024

Materials

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This article deals with the possibility of using 3D-printed models as an input for the production of a mould for cast iron castings. This new progressive process is significantly faster (with sufficient accuracy) compared to the current way of making models for moulds. The need to create a wooden model is removed by this process. The quality of this wooden model was highly dependent on the experience and qualifications of the worker. This article describes the manufacturing process of the model and mould in detail. The key dimensions of the final parts are compared with the model and, thus, the accuracy of the chosen procedure is verified. A 3D-printing technology known as Multi Jet Fusion (MJF) was used to produce the model. The material used for the production of the model is polyamide PA12 with 40% glass fibre filling. This material has sufficient structural and strength properties to be used for the given application. Taking into account the dimensions of the part and the printing space of the printer, it was necessary to structurally modify and divide the part. The inlet cone of a turbine is used as an example This cone is produced from grey cast iron as standard.

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Water Absorption of Underwater Products by Additive Manufacturing

Pino,

Ibáñez-Felip,

Vidal

2024

Materials

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Rapid prototyping techniques offer significant advantages in terms of fabrication speed, accessibility, and low cost. This study explores the use of low-cost stereolithographic resins to produce prototypes intended for underwater conditions. The objective is to evaluate the feasibility of different low-cost resin brands by identifying their water absorption percentage and their response in terms of appearance and deformation after prolonged exposure to an underwater environment. Through three different tests, the suitability of the resins and possible coatings is evaluated, allowing for obtaining data not disclosed by commercial manufacturers and indicating that there are low-cost brands that offer water absorption levels suitable for underwater use. The coefficients for water absorption at saturation begin at 3.3% in saltwater and increase for chlorinated water. Additionally, significant insights are gained regarding the use of coatings. It is found that coatings commonly applied to filament-printed prototypes are generally less suitable for parts produced through stereolithography intended for underwater applications. The most effective strategy is to avoid using coatings altogether.

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Additive Manufacturing in Underwater Applications

Cited by 4 publications

References 127 publications

Evaluating the Mechanical Characteristics of Graphene Nanoparticle-Infused Polyurethane Coating on Low-Density Polylactic Acid Part

Evaluating the Mechanical Characteristics of Graphene Nanoparticle-Infused Polyurethane Coating on Low-Density Polylactic Acid Part

Using a Model Created Using a 3D Printer to Mould a Grey Cast Iron Casting

Water Absorption of Underwater Products by Additive Manufacturing

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