Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain

Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain

In recent years, the development of hybrid powertrain allowed to substantially reduce the CO<sub>2</sub> and pollutant emissions of vehicles. The optimal management of such power units represents a challenging task since more degrees of freedom are available compared to a conventional pu...

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Main Authors: Vincenzo De Bellis, Enrica Malfi, Jean-Marc Zaccardi
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Energies
Subjects:
hybrid powertrain
optimization strategy
computational efficiency
energy management
fuel economy
Online Access:https://www.mdpi.com/1996-1073/14/4/889
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spelling doaj-08fd985c0ff74e869a5543dadeefbf222021-02-09T00:06:30ZengMDPI AGEnergies1996-10732021-02-011488988910.3390/en14040889Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid PowertrainVincenzo De Bellis0Enrica Malfi1Jean-Marc Zaccardi2Dipartimento Di Ingegneria Industriale, Università Degli Studi Di Napoli Federico II, 80125 Napoli, ItalyDipartimento Di Ingegneria Industriale, Università Degli Studi Di Napoli Federico II, 80125 Napoli, ItalyIFP Energies Nouvelles, Institut Carnot IFPEN Transports Energie, Rond-Point De L’échangeur de Solaize, BP 3, 69360 Solaize, FranceIn recent years, the development of hybrid powertrain allowed to substantially reduce the CO<sub>2</sub> and pollutant emissions of vehicles. The optimal management of such power units represents a challenging task since more degrees of freedom are available compared to a conventional pure-thermal engine powertrain. The a priori knowledge of the driving mission allows identifying the actual optimal control strategy at the expense of a quite relevant computational effort. This is realized by the off-line optimization strategies, such as Pontryagin minimum principle—PMP—or dynamic programming. On the other hand, for an on-vehicle application, the driving mission is unknown, and a certain performance degradation must be expected, depending on the degree of simplification and the computational burden of the adopted control strategy. This work is focused on the development of a simplified control strategy, labeled as efficient thermal electric skipping strategy—ETESS, which presents performance similar to off-line strategies, but with a much-reduced computational effort. This is based on the alternative vehicle driving by either thermal engine or electric unit (no power-split between the power units). The ETESS is tested in a “backward-facing” vehicle simulator referring to a segment C car, fitted with a hybrid series-parallel powertrain. The reliability of the method is verified along different driving cycles, sizing, and efficiency of the power unit components and assessed with conventional control strategies. The outcomes put into evidence that ETESS gives fuel consumption close to PMP strategy, with the advantage of a drastically reduced computational time. The ETESS is extended to an online implementation by introducing an adaptative factor, resulting in performance similar to the well-assessed equivalent consumption minimization strategy, preserving the computational effort.https://www.mdpi.com/1996-1073/14/4/889hybrid powertrainoptimization strategycomputational efficiencyenergy managementfuel economy
collection DOAJ
language English
format Article
sources DOAJ
author Vincenzo De Bellis
Enrica Malfi
Jean-Marc Zaccardi
spellingShingle Vincenzo De Bellis
Enrica Malfi
Jean-Marc Zaccardi
Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
Energies
hybrid powertrain
optimization strategy
computational efficiency
energy management
fuel economy
author_facet Vincenzo De Bellis
Enrica Malfi
Jean-Marc Zaccardi
author_sort Vincenzo De Bellis
title Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
title_short Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
title_full Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
title_fullStr Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
title_full_unstemmed Development of an Efficient Thermal Electric Skipping Strategy for the Management of a Series/Parallel Hybrid Powertrain
title_sort development of an efficient thermal electric skipping strategy for the management of a series/parallel hybrid powertrain
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-02-01
description In recent years, the development of hybrid powertrain allowed to substantially reduce the CO<sub>2</sub> and pollutant emissions of vehicles. The optimal management of such power units represents a challenging task since more degrees of freedom are available compared to a conventional pure-thermal engine powertrain. The a priori knowledge of the driving mission allows identifying the actual optimal control strategy at the expense of a quite relevant computational effort. This is realized by the off-line optimization strategies, such as Pontryagin minimum principle—PMP—or dynamic programming. On the other hand, for an on-vehicle application, the driving mission is unknown, and a certain performance degradation must be expected, depending on the degree of simplification and the computational burden of the adopted control strategy. This work is focused on the development of a simplified control strategy, labeled as efficient thermal electric skipping strategy—ETESS, which presents performance similar to off-line strategies, but with a much-reduced computational effort. This is based on the alternative vehicle driving by either thermal engine or electric unit (no power-split between the power units). The ETESS is tested in a “backward-facing” vehicle simulator referring to a segment C car, fitted with a hybrid series-parallel powertrain. The reliability of the method is verified along different driving cycles, sizing, and efficiency of the power unit components and assessed with conventional control strategies. The outcomes put into evidence that ETESS gives fuel consumption close to PMP strategy, with the advantage of a drastically reduced computational time. The ETESS is extended to an online implementation by introducing an adaptative factor, resulting in performance similar to the well-assessed equivalent consumption minimization strategy, preserving the computational effort.
topic hybrid powertrain
optimization strategy
computational efficiency
energy management
fuel economy
url https://www.mdpi.com/1996-1073/14/4/889
work_keys_str_mv AT vincenzodebellis developmentofanefficientthermalelectricskippingstrategyforthemanagementofaseriesparallelhybridpowertrain
AT enricamalfi developmentofanefficientthermalelectricskippingstrategyforthemanagementofaseriesparallelhybridpowertrain
AT jeanmarczaccardi developmentofanefficientthermalelectricskippingstrategyforthemanagementofaseriesparallelhybridpowertrain
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