Your search keyword '"Rule-based control strategy"' showing total 3 results

1. Design and Analysis of Generic Energy Management Strategy for Controlling Second-Life Battery Systems in Stationary Applications.

Author

Abdel-Monem, Mohamed, Hegazy, Omar, Omar, Noshin, Trad, Khiem, De Breucker, Sven, Van Den Bossche, Peter, and Van Mierlo, Joeri

Subjects

*FACILITY management, *POWER electronics, *ENERGY consumption, *STORAGE batteries, *ELECTRICAL load

Abstract

Recently, second-life battery systems have received a growing interest as one of the most promising alternatives for decreasing the overall cost of the battery storage systems in stationary applications. The high-cost of batteries represents a prominent barrier for their use in traction and stationary applications. To make second-life batteries economically viable for stationary applications, an effective power-electronics converter should be selected as well. This converter should be supported by an energy management strategy (EMS), which is needed for controlling the power flow among the second-life battery modules based on their available capacity and performance. This article presents the design, analysis and implementation of a generic energy management strategy (GEMS). The proposed GEMS aims to control and distribute the load demand between battery storage systems under different load conditions and disturbances. This manuscript provides the experimental verification of the proposed management strategy. The results have demonstrated that the GEMS can robustly handle any level of performance inequality among the used-battery modules with the aim to integrate different levels (i.e., size, capacity, and chemistry type) of the second-life battery modules at the same time and in the same application. [ABSTRACT FROM AUTHOR]

Published

2016

2. Design and Analysis of Generic Energy Management Strategy for Controlling Second-Life Battery Systems in Stationary Applications

Author

Mohamed Abdel-Monem, Omar Hegazy, Noshin Omar, Khiem Trad, Sven De Breucker, Peter Van Den Bossche, and Joeri Van Mierlo

Subjects

second-life batteries, energy storage system (ESS), lithium-ion (Li-ion) batteries, stationary applications, self-consumption of photo-voltaic profile, energy/power management strategy, rule-based control strategy, battery management system (BMS), multi-port power converter, Technology

Abstract

Recently, second-life battery systems have received a growing interest as one of the most promising alternatives for decreasing the overall cost of the battery storage systems in stationary applications. The high-cost of batteries represents a prominent barrier for their use in traction and stationary applications. To make second-life batteries economically viable for stationary applications, an effective power-electronics converter should be selected as well. This converter should be supported by an energy management strategy (EMS), which is needed for controlling the power flow among the second-life battery modules based on their available capacity and performance. This article presents the design, analysis and implementation of a generic energy management strategy (GEMS). The proposed GEMS aims to control and distribute the load demand between battery storage systems under different load conditions and disturbances. This manuscript provides the experimental verification of the proposed management strategy. The results have demonstrated that the GEMS can robustly handle any level of performance inequality among the used-battery modules with the aim to integrate different levels (i.e., size, capacity, and chemistry type) of the second-life battery modules at the same time and in the same application.

Published

2016

3. Design and Analysis of Generic Energy Management Strategy for Controlling Second-Life Battery Systems in Stationary Applications

Author

Khiem Trad, Peter Van Den Bossche, Noshin Omar, Sven De Breucker, Omar Hegazy, Joeri Van Mierlo, Mohamed Abdel-Monem, Electromobility research centre, Faculty of Engineering, Electrical Engineering and Power Electronics, Industrial Sciences and Technology, and Engineering Technology

Subjects

Battery (electricity), Engineering, Control and Optimization, Energy management, 020209 energy, Control (management), Energy Engineering and Power Technology, self-consumption of photo-voltaic profile, rule-based control strategy, 02 engineering and technology, lithium-ion (Li-ion) batteries, lcsh:Technology, second-life batteries, energy storage system (ESS), stationary applications, energy/power management strategy, battery management system (BMS), multi-port power converter, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Renewable Energy, Sustainability and the Environment, business.industry, lcsh:T, Electrical engineering, Reliability engineering, Power flow, Management strategy, Battery storage, business, Energy (miscellaneous)

Abstract

Recently, second-life battery systems have received a growing interest as one of the most promising alternatives for decreasing the overall cost of the battery storage systems in stationary applications. The high-cost of batteries represents a prominent barrier for their use in traction and stationary applications. To make second-life batteries economically viable for stationary applications, an effective power-electronics converter should be selected as well. This converter should be supported by an energy management strategy (EMS), which is needed for controlling the power flow among the second-life battery modules based on their available capacity and performance. This article presents the design, analysis and implementation of a generic energy management strategy (GEMS). The proposed GEMS aims to control and distribute the load demand between battery storage systems under different load conditions and disturbances. This manuscript provides the experimental verification of the proposed management strategy. The results have demonstrated that the GEMS can robustly handle any level of performance inequality among the used-battery modules with the aim to integrate different levels (i.e., size, capacity, and chemistry type) of the second-life battery modules at the same time and in the same application.

Published

2016