Your search keyword '"Federico Moro"' showing total 4 results

1. Vibration Energy Harvesting by Means of Piezoelectric Patches: Application to Aircrafts

Author

Domenico Tommasino, Federico Moro, Bruno Bernay, Thibault De Lumley Woodyear, Enrique de Pablo Corona, and Alberto Doria

Subjects

vibration energy harvesting, slat vibrations, multi-physics model, piezoelectric harvester, Chemical technology, TP1-1185

Abstract

Vibration energy harvesters in industrial applications usually take the form of cantilever oscillators covered by a layer of piezoelectric material and exploit the resonance phenomenon to improve the generated power. In many aeronautical applications, the installation of cantilever harvesters is not possible owing to the lack of room and/or safety and durability requirements. In these cases, strain piezoelectric harvesters can be adopted, which directly exploit the strain of a vibrating aeronautic component. In this research, a mathematical model of a vibrating slat is developed with the modal superposition approach and is coupled with the model of a piezo-electric patch directly bonded to the slat. The coupled model makes it possible to calculate the power generated by the strain harvester in the presence of the broad-band excitation typical of the aeronautic environment. The optimal position of the piezoelectric patch along the slat length is discussed in relation with the modes of vibration of the slat. Finally, the performance of the strain piezoelectric harvester is compared with the one of a cantilever harvester tuned to the frequency of the most excited slat mode.

Published

2022

2. Development of a Novel Piezoelectric Harvester Excited by Raindrops

Author

Alberto Doria, Giulio Fanti, Gino Filipi, and Federico Moro

Subjects

raindrop energy harvester, impulse vibrations, piezoelectric, Chemical technology, TP1-1185

Abstract

The impact of raindrops on a dry surface leads to a splashing phenomenon that dissipates a lot of energy. To improve energy collection, a novel piezoelectric raindrop energy harvester equipped with a spoonful of water was developed. The advantages and the drawbacks of this solution were analyzed with the aid of numerical simulations. A series of experimental tests were carried out in a laboratory with simulated raindrops. Experimental results showed that the negative effect of the added water mass was exceeded by the positive effects related to the impact of the raindrop on a liquid surface. Tests carried out connecting the harvester to a resistive load showed that the prototype was able to collect more energy than a simple cantilever harvester.

Published

2019

3. Development of a Novel Piezoelectric Harvester Excited by Raindrops

Author

Gino Filipi, Alberto Doria, Giulio Fanti, and Federico Moro

Subjects

Cantilever, Materials science, Acoustics, 02 engineering and technology, lcsh:Chemical technology, raindrop energy harvester, Biochemistry, Article, Energy harvester, Analytical Chemistry, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, impulse vibrations, piezoelectric, 020208 electrical & electronic engineering, 021001 nanoscience & nanotechnology, Piezoelectricity, Atomic and Molecular Physics, and Optics, Excited state, Resistive load, Development (differential geometry), 0210 nano-technology, Energy (signal processing)

Abstract

The impact of raindrops on a dry surface leads to a splashing phenomenon that dissipates a lot of energy. To improve energy collection, a novel piezoelectric raindrop energy harvester equipped with a spoonful of water was developed. The advantages and the drawbacks of this solution were analyzed with the aid of numerical simulations. A series of experimental tests were carried out in a laboratory with simulated raindrops. Experimental results showed that the negative effect of the added water mass was exceeded by the positive effects related to the impact of the raindrop on a liquid surface. Tests carried out connecting the harvester to a resistive load showed that the prototype was able to collect more energy than a simple cantilever harvester.

Published

2019

4. A Workflow for Studying the Stump–Socket Interface in Persons with Transtibial Amputation through 3D Thermographic Mapping

Author

Andrea Giovanni Cutti, Federico Morosato, Cosimo Gentile, Francesca Gariboldi, Giovanni Hamoui, Maria Grazia Santi, Gregorio Teti, and Emanuele Gruppioni

Subjects

3D thermography, thermal imaging, lower limb amputation, Chemical technology, TP1-1185

Abstract

The design and fitting of prosthetic sockets can significantly affect the acceptance of an artificial limb by persons with lower limb amputations. Clinical fitting is typically an iterative process, which requires patients’ feedback and professional assessment. When feedback is unreliable due to the patient’s physical or psychological conditions, quantitative measures can support decision-making. Specifically, monitoring the skin temperature of the residual limb can provide valuable information regarding unwanted mechanical stresses and reduced vascularization, which can lead to inflammation, skin sores and ulcerations. Multiple 2D images to examine a real-life 3D limb can be cumbersome and might only offer a partial assessment of critical areas. To overcome these issues, we developed a workflow for integrating thermographic information on the 3D scan of a residual limb, with intrinsic reconstruction quality measures. Specifically, workflow allows us to calculate a 3D thermal map of the skin of the stump at rest and after walking, and summarize this information with a single 3D differential map. The workflow was tested on a person with transtibial amputation, with a reconstruction accuracy lower than 3 mm, which is adequate for socket adaptation. We expect the workflow to improve socket acceptance and patients’ quality of life.

Published

2023