Your search keyword '"Bongiorno, F"' showing total 10 results

1. Fatigue Behaviour of High-Performance Green Epoxy Biocomposite Laminates Reinforced by Optimized Long Sisal Fibers.

Author

Zuccarello, B., Militello, C., and Bongiorno, F.

Subjects

FATIGUE limit, FATIGUE life, MATERIAL fatigue, CARBON steel, FATIGUE testing machines, NATURAL fibers, SISAL (Fiber)

Abstract

In recent decades, in order to replace traditional synthetic polymer composites, engineering research has focused on the development of new alternatives such as green biocomposites constituted by an eco-sustainable matrix reinforced by natural fibers. Such innovative biocomposites are divided into two different typologies: random short fiber biocomposites characterized by low mechanical strength, used for non-structural applications such as covering panels, etc., and high-performance biocomposites reinforced by long fibers that can be used for semi-structural and structural applications by replacing traditional materials such as metal (carbon steel and aluminum) or synthetic composites such as fiberglass. The present research work focuses on the high-performance biocomposites reinforced by optimized sisal fibers. In detail, in order to contribute to the extension of their application under fatigue loading, a systematic experimental fatigue test campaign has been accomplished by considering four different lay-up configurations (unidirectional, cross-ply, angle-ply and quasi-isotropic) with volume fraction Vf = 70%. The results analysis found that such laminates exhibit good fatigue performance, with fatigue ratios close to 0.5 for unidirectional and angle-ply (±7.5°) laminates. However, by passing from isotropic to unidirectional lay-up, the fatigue strength increases significantly by about four times; higher increases are revealed in terms of fatigue life. In terms of damage, it has been observed that, thanks to the high quality of the proposed laminates, in any case, the fatigue failure involves the fiber failure, although secondary debonding and delamination can occur, especially in orthotropic and cross-ply lay-up. The comparison with classical synthetic composites and other similar biocomposite has shown that in terms of fatigue ratio, the examined biocomposites exhibit performance comparable with the biocomposites reinforced by the more expensive flax and with common fiberglass. Finally, appropriate models, that can be advantageously used at the design stage, have also been proposed to predict the fatigue behavior of the laminates analyzed. [ABSTRACT FROM AUTHOR]

Published

2024

2. Histories of Australian Democracy: Australian Centre for Public History UTS Working Paper

Author

Pietsch, T, Bongiorno, F, Clark, A, Flanagan, F, Rubenstein, K, Schultz, J, Wallace, C, Pietsch, T, Bongiorno, F, Clark, A, Flanagan, F, Rubenstein, K, Schultz, J, and Wallace, C

Published

2023

3. Histories of Australian Democracy

Author

Pietsch, T, Bongiorno, F, Clark, A, Flanagan, F, Rubenstein, K, Schultz, J, Wallace, C, Pietsch, T, Bongiorno, F, Clark, A, Flanagan, F, Rubenstein, K, Schultz, J, and Wallace, C

Abstract

Research Report for Dept. Home Affairs

Published

2023

4. New Histories and the Return of Crisis: Labour History at 60

Author

Bongiorno, Frank

Published

2022

5. First lamina hybridization of high performance CFRP with Kevlar fibers: Effect on impact behavior and nondestructive evaluation

Author

Carmelo Militello, Gabriella Epasto, Francesco Bongiorno, Bernardo Zuccarello, Militello C., Epasto G., Bongiorno F., and Zuccarello B.

Subjects

Mechanics of Materials, phased array ultrasonic technique, x-rays techniques, Mechanical Engineering, General Mathematics, infrared thermography, Hybrid composites, General Materials Science, Damage assessment, low velocity impact, Civil and Structural Engineering

Abstract

The impact behavior of a carbon-Kevlar hybrid composite, widely used in sport car manufacturing, was evaluated. To highlight the hybridization effect, comparative analyses were performed with the basic CFRP laminate having the same lay-up. Tensile, bending and low velocity impact tests, followed by nondestructive inspections, highlighted that Kevlar first lamina hybridization leads to an increment in specific impact strength, up to 55%. To assess the most reliable technique to detect the impact damage, nondestructive evaluation was performed by pulsed thermography, phased array ultrasonic technique, computed tomography and digital radiography. Phased array ultrasonic technique can be considered the most appropriate technique.

Published

2022

6. Environmental aging effects on high-performance biocomposites reinforced by sisal fibers

Author

Bernardo Zuccarello, Carmelo Militello, Francesco Bongiorno, Zuccarello B., Militello C., and Bongiorno F.

Subjects

Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Polymers and Plastics, Mechanics of Materials, Materials Chemistry, Mechanical properties, Condensed Matter Physics, Biocomposite, Sisal fiber, Environmental degradation

Abstract

Among the innovative materials, an important role is played by the so-called biocomposites, generally made by an eco-friendly matrix reinforced with natural fibers. Unfortunately, due to the degradability of the green matrixes as well as to hydrophilicity of the natural fibers, the resistance of such innovative materials to the environmental agents is, in general, relativity low, and it can significantly limit their use in outdoor conditions. To contribute to the knowledge of the effects of the leading environmental agents on the mechanical properties of highperformance biocomposites made of a green epoxy matrix reinforced by agave fibers, a systematic experimental testing campaign has been carried out by considering three types of biocomposite laminates (unidirectional, cross-ply and quasi-isotropic with a Vf = 70%). In detail, the different effects of aging on matrix and reinforcement have been highlighted by also considering samples consisting of simple epoxy matrix alone. The usual outdoor operating conditions associated with frequent exposure to sunlight (temperature and UV cycles) and humidity have been reproduced by subjecting the biocomposites to an accelerated aging process. Successive tensile and delamination tests have shown that aging leads to significant mechanical properties reductions, ranging from about 40% (tensile) to about 70% (delamination). A systematic analysis of the experimental results has allowed to develop reliable models that can be used to predict the degradation affecting the mechanical properties when these biocomposites are subjected to the actual aging related to the outdoor service conditions.

Published

2023

7. Mode I translaminar fracture toughness of high performance laminated biocomposites reinforced by sisal fibers: Accurate measurement approach and lay-up effects

Author

Carmelo Militello, F Bongiorno, Bernardo Zuccarello, Bongiorno F., Militello C., and Zuccarello B.

Subjects

Toughness, Materials science, General Engineering, Fracture mechanics, Epoxy, Bio composites, Fracture toughness, Natural fibre composites, Translaminar failure, R-curves, Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, Fracture toughness, visual_art, Ceramics and Composites, visual_art.visual_art_medium, Fracture (geology), Fiber, Composite material, Anisotropy, computer, SISAL, computer.programming_language

Abstract

The present work performs a systematic experimental analysis of the translaminar fracture behavior of high performance biocomposites constituted by green epoxy reinforced by sisal fibers, by varying the main influence parameters as fiber concentration and lay-up. Despite the corrective function properly introduced to take into account the anisotropy as well as the use of the equivalent crack length, the study shows that the LEFM does not give accurate estimations of the fracture toughness, because the extension of the near tip damaged zone is higher than the singular dominated one. Accurate estimations can be obtained instead by the proposed modified area method that takes into account both the local damage and the fiber bridging that occurs during crack propagation, that lead to R-curves whose asymptotic values constitute the true fracture toughness of the biocomposites examined. The constancy of the damage mechanisms observed by varying the fiber concentration, allows the user to compute the fracture toughness of a generic laminate from the specific fracture energy of the unidirectional lamina. Finally, the relatively high fracture toughness of the examined laminates allows to state that they can advantageously replace not only other composites having lower toughness, but also metals as steel, aluminum and titanium.

Published

2022

8. Analysis of the Parameters Affecting the Stiffness of Short Sisal Fiber Biocomposites Manufactured by Compression-Molding

Author

Antonio Pantano, Carmelo Militello, Francesco Bongiorno, Bernardo Zuccarello, Pantano A., Militello C., Bongiorno F., and Zuccarello B.

Subjects

Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di Macchine, QD241-441, Biocomposites, Polymers and Plastics, Organic chemistry, General Chemistry, Numerical methods, Natural fibers, Article, Sisal, biocomposites, natural fibers, sisal, numerical methods

Abstract

The use of natural fiber-based composites is on the rise in many industries. Thanks to their eco-sustainability, these innovative materials make it possible to adapt the production of components, systems and machines to the increasingly stringent regulations on environmental protection, while at the same time reducing production costs, weight and operating costs. Optimizing the mechanical properties of biocomposites is an important goal of applied research. In this work, using a new numerical approach, the effects of the volume fraction, average length, distribution of orientation and curvature of fibers on the Young’s modulus of a biocomposite reinforced with short natural fibers were studied. Although the proposed approach could be applied to any biocomposite, sisal fibers and an eco-sustainable thermosetting matrix (green epoxy) were considered in both simulations and the associated experimental assessment. The results of the simulations showed the following effects of the aforementioned parameters on Young’s modulus: a linear growth with the volume fraction, nonlinear growth as the length of the fibers increased, a reduction as the average curvature increased and an increase in stiffness in the x-y plane as the distribution of fiber orientation in the z direction decreased.

Published

2021

9. Basalt Fiber Hybridization Effects on High-Performance Sisal-Reinforced Biocomposites.

Author

Zuccarello B, Bongiorno F, and Militello C

Abstract

The increasing attention given to environmental protection, largely through specific regulations on environmental impact and the recycling of materials, has led to a considerable interest of researchers in biocomposites, materials consisting of bio-based or green polymer matrixes reinforced by natural fibers. Among the various reinforcing natural fibers, sisal fibers are particularly promising for their good mechanical properties, low specific weight and wide availability on the current market. As proven in literature by various authors, the hybridization of biocomposites by synthetical fibers or different natural fibers can lead to an interesting improvement of the mechanical properties or, in turn, of the strength against environmental agents. Consequently, this can lead to a significant enlargement of their practical applications, in particular from quite common non-structural applications (dashboards, fillings, soundproofing, etc.) towards semi-structural (panels, etc.) and structural applications (structural elements of civil construction and/or machine components). Hybridizations with natural fibers or with ecofriendly basalt fibers are the most interesting ones, since they permit the improvement of the biocomposite's performance without an appreciable increment on environmental impact, as occurs instead for synthetic fiber hybridizations that are also widely proposed in the literature. In order to further increase the mechanical performance and, above all, to reduce the aging effects on high-performance sisal-reinforced biocomposites due to environmental agents, the hybridization of such biocomposites with basalt fibers are studied with tensile, compression and delamination tests performed by varying the exposition to environmental agents. In brief, the experimental analysis has shown that hybridization can lead to further enhancements of mechanical performance (strength and stiffness) that increase with basalt volume fraction and can lead to appreciable reductions in the aging effects on mechanical performance by simple hybridization of the surface laminae. Therefore, such a hybridization can be advantageously used in all practical outdoor applications in which high-performance sisal biocomposites can be exposed to significant environmental agents (temperature, humidity, UV).

Published

2022

10. Analysis of the Parameters Affecting the Stiffness of Short Sisal Fiber Biocomposites Manufactured by Compression-Molding.

Author

Pantano A, Militello C, Bongiorno F, and Zuccarello B

Abstract

The use of natural fiber-based composites is on the rise in many industries. Thanks to their eco-sustainability, these innovative materials make it possible to adapt the production of components, systems and machines to the increasingly stringent regulations on environmental protection, while at the same time reducing production costs, weight and operating costs. Optimizing the mechanical properties of biocomposites is an important goal of applied research. In this work, using a new numerical approach, the effects of the volume fraction, average length, distribution of orientation and curvature of fibers on the Young's modulus of a biocomposite reinforced with short natural fibers were studied. Although the proposed approach could be applied to any biocomposite, sisal fibers and an eco-sustainable thermosetting matrix (green epoxy) were considered in both simulations and the associated experimental assessment. The results of the simulations showed the following effects of the aforementioned parameters on Young's modulus: a linear growth with the volume fraction, nonlinear growth as the length of the fibers increased, a reduction as the average curvature increased and an increase in stiffness in the x - y plane as the distribution of fiber orientation in the z direction decreased.

Published

2021