Your search keyword '"Cardelli, Ermanno"' showing total 5 results

1. Vector Hysteresis Processes for Innovative Fe-Si Magnetic Powder Cores: Experiments and Neural Network Modeling.

Author

Antonio, Simone Quondam, Fulginei, Francesco Riganti, Faba, Antonio, Chilosi, Francesco, and Cardelli, Ermanno

Subjects

HYSTERESIS, MAGNETIC particles, ELECTROMAGNETIC induction, ARTIFICIAL neural networks, FINITE element method, MAGNETIC measurements

Abstract

A thorough investigation of the 2-D hysteresis processes under arbitrary excitations was carried out for a specimen of innovative Fe-Si magnetic powder material. The vector experimental measurements were first performed via a single disk tester (SDT) apparatus under a controlled magnetic induction field, taking into account circular, elliptic, and scalar processes. The experimental data relative to the circular loops were utilized to identify a vector model of hysteresis based on feedforward neural networks (NNs), having as an input the magnetic induction vector B and as an output the magnetic field vector H. Then the model was validated by the simulation of the other experimental hysteresis processes. The comparison between calculated and measured loops evidenced the capability of the model in both the reconstruction of the magnetic field trajectory and the prediction of the power loss under various excitation waveforms. Finally, the computational efficiency of the model makes it suitable for future application in finite element analysis (FEA). [ABSTRACT FROM AUTHOR]

Published

2021

2. Energy from the Waves: Integration of a HESS to a Wave Energy Converter in a DC Bus Electrical Architecture to Enhance Grid Power Quality.

Author

Barelli, Linda, Cardelli, Ermanno, Pelosi, Dario, Ciupageanu, Dana Alexandra, Ottaviano, Panfilo Andrea, Longo, Michela, and Zaninelli, Dario

Subjects

*WAVE energy, *ENERGY storage, *ELECTRIC motor buses, *ELECTRIC power distribution grids, *RENEWABLE energy sources, *ENERGY conversion

Abstract

The need for environmental protection is pushing to a massive introduction of energy production from renewables. Although wind and solar energy present the most mature technologies for energy generation, wave energy has a huge annual energy potential not exploited yet. Indeed, no leading device for wave energy conversion has already been developed. Hence, the future exploitation of wave energy will be strictly related to a specific infrastructure for power distribution and transmission that has to satisfy high requirements to guarantee grid safety and stability, because of the stochastic nature of this source. To this end, an electrical architecture model, based on a common DC bus topology and including a Hybrid Energy Storage System (HESS) composed by Li-ion battery and flywheel coupled to a wave energy converter, is here presented. In detail, this research work wants to investigate the beneficial effects in terms of voltage and current waveforms frequency and transient behavior at the Point of Common Coupling (PCC) introduced by HESS under specific stressful production conditions. Specifically, in the defined simulation scenarios it is demonstrated that the peak value of the voltage wave frequency at the PCC is reduced by 64% to 80% with a faster stabilization in the case of HESS with respect to storage absence, reaching the set value (50 Hz) in a shorter time (by −10% to −42%). Therefore, HESS integration in wave energy converters can strongly reduce safety and stability issues of the main grid relating to intermittent and fluctuating wave production, significantly increasing the tolerance to the expected increasing share of electricity from renewable energy sources. [ABSTRACT FROM AUTHOR]

Published

2022

3. Influence of Non-Linearity in Losses Estimation of Magnetic Components for DC-DC Converters.

Author

Corti, Fabio, Reatti, Alberto, Lozito, Gabriele Maria, Cardelli, Ermanno, and Laudani, Antonino

Subjects

DC-to-DC converters, MAGNETIC flux leakage, MAGNETIC materials, MAGNETIC devices, MAGNETIC cores, ELECTRIC current rectifiers

Abstract

In this paper, the problem of estimating the core losses for inductive components is addressed. A novel methodology is applied to estimate the core losses of an inductor in a DC-DC converter in the time-domain. The methodology addresses both the non-linearity and dynamic behavior of the core magnetic material and the non-uniformity of the field distribution for the device geometry. The methodology is natively implemented using the LTSpice simulation environment and can be used to include an accurate behavioral model of the magnetic devices in a more complex lumped circuit. The methodology is compared against classic estimation techniques such as Steinmetz Equation and the improved Generalized Steinmetz Equation. The validation is performed on a practical DC-DC Buck converter, which was utilized to experimentally verify the results derived by a model suitable to estimate the inductor losses. Both simulation and experimental test confirm the accuracy of the proposed methodology. Thus, the proposed technique can be flexibly used both for direct core loss estimation and the realization of a subsystem able to simulate the realistic behavior of an inductor within a more complex lumped circuit. [ABSTRACT FROM AUTHOR]

Published

2021

4. Design and Comparison of the Performance of 12-Pulse Rectifiers for Aerospace Applications.

Author

Corti, Fabio, Hassan Shehata, Abdelazeem, Laudani, Antonino, and Cardelli, Ermanno

Subjects

TIME-domain analysis, MAGNETIC flux leakage, ELECTRIC current rectifiers

Abstract

In this paper, a conventional 12-pulse transformer unit (CTU) and an autotransformer 12-pulse transformer unit (ATU) are compared in the view of the RTCA DO-160 standard for aircraft applications. The design of the magnetic components is proposed via a coupled FEM-circuital analysis in the time domain for an 800 Hz/2 kW system. Input AC distortion, power factor, and output DC ripple are evaluated through simulations. An accurate power loss analysis is carried out, taking into account copper losses, magnetic losses, and power losses due to power switches. The reduction in the size and weight of the ATU with respect to the CTU solution is discussed, including the need for filtering systems and the standard requirements. [ABSTRACT FROM AUTHOR]

Published

2021

5. Properties of Additively Manufactured Electric Steel Powder Cores with Increased Si Content.

Author

Stornelli, Giulia, Faba, Antonio, Di Schino, Andrea, Folgarait, Paolo, Ridolfi, Maria Rita, Cardelli, Ermanno, Montanari, Roberto, and Gromov, Alexander A.

Subjects

ELECTRICAL steel, SILICON steel, STEEL manufacture, COREMAKING, MAGNETIC cores, EPITAXY

Abstract

In this paper, the best laser powder bed fusion (L-PBF) printing conditions for FeSi steels with two different Si content (3.0% and 6.5%) are defined. Results show very strict processing window parameters, following a lack of fusion porosity at low specific energy values and keyhole porosity in correspondence with high specific energy values. The obtained microstructure consists of grains with epitaxial growth starting from the grains already solidified in the underling layer. This allows the continuous growth of the columnar grains, directed parallel to the built direction of the component. The magnetic behaviour of FeSi6.5 samples, although the performances found do not still fully reach those of the best commercial electrical steels (used to manufacture magnetic cores of electrical machines and other similar magnetic components), appears to be quite promising. An improvement of the printing process to obtain thin sheets with increased Si content, less than 0.5 mm thick, with accurate geometry and robust structures, can result to an interesting technology for specific application where complex geometries and sophisticated shapes are required, avoiding mechanical machining processes for electrical steel with high silicon content. [ABSTRACT FROM AUTHOR]

Published

2021