Your search keyword '"Porpora, F."' showing total 3 results

1. Design methodology for passive balancing circuit including real battery operating conditions

Author

Matilde D'Arpino, C. Attaianese, Francesco Porpora, Giuseppe Tomasso, Mauro Di Monaco, Monaco, M. D., Porpora, F., Tomasso, G., D'Arpino, M., and Attaianese, C.

Subjects

Battery (electricity), Lithium-ion batteries, Equalizer circuit, Iterative methods, Computer science, Equalization (audio), 02 engineering and technology, Lithium-ion battery, law.invention, Reliability (semiconductor), 0203 mechanical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, BMS, Electronic circuit, Electronic countermeasures, 020208 electrical & electronic engineering, Resistors, 020302 automobile design & engineering, Battery pack, Integrated circuit modeling, Resistors, Iterative methods, Electronic countermeasures, Design methodology, Lithium-ion batteries, Integrated circuit modeling, Design methodology, Resistor, Passive balancing, Voltage

Abstract

The passive balancing (PB) circuits are still the most common solution for the voltage equalization of series-connected battery cells due to the higher reliability, lower cost and control simplicity compared to the active balancing (AB) ones. PB circuits are usually designed considering a desired equalization time and constraints on size and power dissipation of the equalization resistors. However, the performance of the PB circuits strongly depend on the battery cells technology as well as the voltage imbalance condition between the most charged cell and the least charged one of a series-connected battery pack. Therefore, additional parameters need to be considered for optimizing the design of the PB circuits. This paper presents a systematic approach for the design of PB circuits for lithium-ion battery packs that takes into account for real cells operating conditions. An extensive numerical analysis is reported to demonstrate the validity of the proposed methodology.

Published

2020

2. Thermal Management Optimization of a Passive BMS for Automotive Applications

Author

Mauro Di Monaco, Giuseppe Tomasso, Umberto Abronzini, Matilde D'Arpino, C. Attaianese, Francesco Porpora, Abronzini, U., Di Monaco, M., Porpora, F., Tomasso, G., D'Arpino, M., and Attaianese, C.

Subjects

Electric Vehicle, Battery (electricity), business.industry, Computer science, 020209 energy, 020208 electrical & electronic engineering, Equalization (audio), Automotive industry, Process (computing), Control engineering, 02 engineering and technology, Thermal management of electronic devices and systems, Energy Storage, Battery Management System, Energy storage, Battery management systems, Thermal Management, 0202 electrical engineering, electronic engineering, information engineering, Electric Vehicles, Thermal model, business

Abstract

This paper deals with a new adaptive balancing control algorithm for passive and distributed Battery Management System (BMS) for automotive applications. A calibrated first-order model for the battery cells and thermal model of the BMS slaves unit have been considered in the development of the proposed control. It performs the balancing process of the cells by managing the temperature of the BMS slave unit. Taking into account the thermal constraints of the system, the proposed control dynamically selects the number of the cells to be balanced for each battery module and the optimal temperature of the BMS slave units in order to minimize the equalization time. A deep numerical analysis is presented to validate the performance of the proposed approach.

Published

2019

3. Optimal Modular BMS for High Performances NMC Battery Pack

Author

Maurizio Granato, Giovanni Frattini, Mauro Di Monaco, Francesco Porpora, Ciro Attaianese, Umberto Abronzini, Giuseppe Tomasso, Abronzini, U., Attaianese, C., Monaco, M. D., Porpora, F., Tomasso, G., Granato, M., and Frattini, G.

Subjects

Battery Management System (BMS), battery pack, Electric Motor Racing (EMR), Motor racing, Modular structure, business.industry, Computer science, 020208 electrical & electronic engineering, Equalization (audio), 020302 automobile design & engineering, 02 engineering and technology, Change control board, Modular design, Battery pack, Automotive engineering, Power (physics), Microcontroller, 0203 mechanical engineering, 0202 electrical engineering, electronic engineering, information engineering, business

Abstract

This paper deals with the design and the implementation of a passive modular battery management system (BMS) for high power battery packs, designed for motorsport applications. The modular structure of the BMS is composed of a power board for the passive balancing of the cells and a control board based on Texas Instruments®BQ76PL455-Q1 device. The proposed system is designed to meet the restricted specifications of a motor racing application like E-Kart. In detail, an optimized BMS algorithm is proposed, which allows achieving high performance in terms of safety and equalization time.

Published

2019