Your search keyword '"Serra, Gabriel F."' showing total 5 results

1. Shear thickening fluid (STF) in engineering applications and the potential of cork in STF-based composites

Author

Serra, Gabriel F., Oliveira, Lídia, Gürgen, Selim, de Sousa, R.J. Alves, and Fernandes, Fábio A.O.

Published

2024

2. Experimental and Numerical Insights into the Multi-Impact Response of Cork Agglomerates.

Author

Antunes e Sousa, Guilherme J., Silva, Afonso J. C., Serra, Gabriel F., Fernandes, Fábio A. O., Silva, Susana P., and Alves de Sousa, Ricardo J.

Subjects

FINITE element method, IMPACT testing, STRAIN rate, MATERIAL plasticity, DYNAMIC testing, CORK

Abstract

Due to their extraordinary qualities, including fire resistance, excellent crashworthiness, low thermal conductivity, permeability, non-toxicity, and reduced density, cellular materials have found extensive use in various engineering applications. This study uses a finite element analysis (FEA) to model the dynamic compressive behaviour of agglomerated cork to ascertain how its material density and stress relaxation behaviour are related. Adding the Mullins effect into the constitutive modelling of impact tests, its rebound phase and subsequent second impact were further examined and simulated. Quasi-static and dynamic compression tests were used to evaluate the mechanical properties of three distinct agglomerated cork composite samples to feed the numerical model. According to the results, agglomerated cork has a significant capacity for elastic rebound, especially under dynamic strain rates, with minimal permanent deformation. For instance, the minimum value of its bounce-back energy is 11.8% of the initial kinetic energy, and its maximum permanent plastic deformation is less than 10%. The material's model simulation adequately depicts the agglomerated cork's response to initial and follow-up impacts by accurately reproducing the material's dynamic compressive behaviour. In terms of innovation, this work stands out since it tackles the rebounding phenomena, which was not previously investigated in this group's prior publication, either numerically or experimentally. Thus, this group has expanded the research on cork materials' attributes. [ABSTRACT FROM AUTHOR]

Published

2024

3. Head protection in electric micromobility: A critical review, recommendations, and future trends

Author

Serra, Gabriel F., Fernandes, Fábio A.O., Noronha, Eduardo, and de Sousa, Ricardo J. Alves

Published

2021

4. Eco-Friendly Cork–Polyurethane Biocomposites for Enhanced Impact Performance: Experimental and Numerical Analysis.

Author

Dymek, Mateusz, Ptak, Mariusz, Kaczyński, Paweł, Fernandes, Fábio A. O., Alves de Sousa, Ricardo J., Serra, Gabriel F., and Kurańska, Maria

Subjects

CORK, EDIBLE fats & oils, NUMERICAL analysis, POLYOLS, FINITE element method, PETROLEUM waste, URETHANE foam, VEGETABLE oils

Abstract

Cork composites are byproducts from wine stopper production, resulting from the agglomeration of cork granules with a thermoset resin. The resulting compound is a versatile and durable material with numerous industrial applications. Due to its unique properties, such as low-density, high-strength, excellent energy absorption, and good thermal and acoustic insulators, cork composites find room for application in demanding industries such as automotive, construction, and aerospace. However, agglomerated cork typically has a polyurethane matrix derived from petrochemical sources. This study focuses on developing eco-friendly porous polyurethane biocomposites manufactured with the used cooking oil polyol modified with cork. Since cork and polyurethane foam are typically used for impact shock absorption, the manufactured samples were subjected to impact loading. The assessment of crashworthiness is performed through 100 J impact tests. A finite element numerical model was developed to simulate the compression of these new composites under impact, and the model validation was performed. The highest specific absorbed energy was obtained for petrochemical polyol composites with the 3% addition of natural or modified cork. The research conducted in this study showcased the feasibility of substituting certain petrochemical components used for the synthesis of the polyurethane matrix with ecological waste vegetable oil components. [ABSTRACT FROM AUTHOR]

Published

2024

5. Expanded (Black) Cork for the Development of an Eco-Friendly Surfboard: Environmental Impact and Mechanical Properties.

Author

Correia, José M. D., Serra, Gabriel F., Alves de Sousa, Ricardo J., Pereira, António B., and Fernandes, Fábio A. O.

Abstract

Based on global needs for sustainable development, finding new sustainable materials that can replace oil-based ones for mass products is crucial nowadays. This paper focuses on employing an expanded cork-based composite to produce a surfboard. To evaluate the mechanical properties, uniaxial tensile and compression tests were performed on the skin and core materials, respectively. Bending tests were performed on the entire representative composite structure. Numerical models of the tests were arranged and validated from experimental results. From that, a surfboard prototype model was used to simulate some experimental conditions, permitting us to draw promising conclusions. An actual prototype was also produced. It was found that expanded cork performs very well when sandwiched between wood and polyester resin/glass fibre, being able to hold substantial loads and at the same time reduce weight and the environmental footprint of the composite by 62.8%. It can be concluded that expanded cork is an excellent candidate to replace oil-based foams in surfboard manufacturing. Despite a slight increase in weight, this sustainable material aligns with all the philosophies of surf practice worldwide. [ABSTRACT FROM AUTHOR]

Published

2022