Energy Management for a Fuel Cell Plug-In Hybrid Heavy-Duty Vehicle

Erik Skeel; Ari Hentunen; Mikko Pihlatie; Jari Vepsäläinen; Mikaela Ranta; Prashant Singh; Sai Santhosh Tota

doi:10.3390/wevj17050233

Energy Management for a Fuel Cell Plug-In Hybrid Heavy-Duty Vehicle

Erik Skeel^*
, Ari Hentunen
, Mikko Pihlatie
, Jari Vepsäläinen
, Mikaela Ranta
, Prashant Singh
, Sai Santhosh Tota

^*Corresponding author for this work

Aalto University

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Decarbonizing heavy-duty road freight transportation requires efficient energy management in zero-emission powertrains. This study investigates energy management strategies (EMSs) for a heavy-duty Fuel Cell Plug-in Hybrid Electric Vehicle (FC-PHEV). Rather than the typical charge-sustaining operation, these strategies are designed for charge-depleting operation, in which each route begins with a charged battery and ends at a lower state of charge (SOC), leveraging the vehicle’s plug-in capability. The EMSs are evaluated primarily in terms of energy consumption, while battery C-rate and fuel cell ramp rate are used as simple stress indicators for comparative analysis. A backward-facing vehicle model is developed to test several EMSs, including both optimization- and rule-based strategies. The Equivalent Consumption Minimization Strategy (ECMS) emerged as a promising option, motivating further testing with a forward-facing model and additional drive cycles. The simulation results show that ECMS consumed only 1.1% more energy than the global optimal solution found by Pontryagin’s Minimum Principle (PMP) and 7.5% less energy than a simple rule-based strategy, on average across five drive cycles. These results show that ECMS can be effective for a heavy-duty FC-PHEV operating in charge-depleting mode, extending its demonstrated applicability beyond charge-sustaining and light-duty vehicles.

Original language	English
Article number	233
Journal	World Electric Vehicle Journal
Volume	17
Issue number	5
DOIs	https://doi.org/10.3390/wevj17050233
Publication status	Published - 28 Apr 2026
MoE publication type	A1 Journal article-refereed

Funding

This work was supported by the ESCALATE project which has received funding from the European Union’s Horizon Europe research and innovation program under grant agreement ID: 101096598. This work was also funded by European Union NextGenerationEU project, which is part of the strategic research opening “Electric Storage” of VTT, launched with the support of the additional chapter of the RePowerEU investment and reform programme for sustainable growth in Finland. Additionally, this work was supported by the Research Council of Finland via the THERMAZEV project (grant number 363654).

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

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10.3390/wevj17050233Licence: CC BY

wevj17050233Final published version, 1.06 MBLicence: CC BY

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THERMAZEV: Thermal management for real zero-emission vehicles
Pihlatie, M. (Manager), Rahkola, P. (Participant), Ranta, M. (Participant), Muona, T. (Participant), Singh, P. (Participant), Arora, S. (Participant), Tota, S. (Participant), Hentunen, A. (Participant), Ihonen, J. (Participant), Alimbekova, A. (Participant), Skeel, E. (Participant), Dixit, P. (Participant), Santasalo-Aarnio, A. (Manager) & Pallonen, L. (Participant)
13/06/24 → 31/12/28
Project: Research Council of Finland
ESCALATE: Powering EU Net Zero Future by Escalating Zero Emission HDVs and Logistic Intelligence
Pihlatie, M. (Manager), Antila, M. (Participant), Ihonen, J. (Participant), Åman, R. (Participant), Vänttinen, L. (Participant), Ranta, M. (Participant), Anttila, J. (Participant), Skeel, E. (Participant), Tota, S. (Participant) & Singh, P. (Participant)
1/01/23 → 30/06/26
Project: EU project
REPowerEU at VTT
Funded by the European Union
1/01/24 → 31/12/25
Project: Finnish government project

Cite this

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title = "Energy Management for a Fuel Cell Plug-In Hybrid Heavy-Duty Vehicle",

abstract = "Decarbonizing heavy-duty road freight transportation requires efficient energy management in zero-emission powertrains. This study investigates energy management strategies (EMSs) for a heavy-duty Fuel Cell Plug-in Hybrid Electric Vehicle (FC-PHEV). Rather than the typical charge-sustaining operation, these strategies are designed for charge-depleting operation, in which each route begins with a charged battery and ends at a lower state of charge (SOC), leveraging the vehicle{\textquoteright}s plug-in capability. The EMSs are evaluated primarily in terms of energy consumption, while battery C-rate and fuel cell ramp rate are used as simple stress indicators for comparative analysis. A backward-facing vehicle model is developed to test several EMSs, including both optimization- and rule-based strategies. The Equivalent Consumption Minimization Strategy (ECMS) emerged as a promising option, motivating further testing with a forward-facing model and additional drive cycles. The simulation results show that ECMS consumed only 1.1\% more energy than the global optimal solution found by Pontryagin{\textquoteright}s Minimum Principle (PMP) and 7.5\% less energy than a simple rule-based strategy, on average across five drive cycles. These results show that ECMS can be effective for a heavy-duty FC-PHEV operating in charge-depleting mode, extending its demonstrated applicability beyond charge-sustaining and light-duty vehicles.",

author = "Erik Skeel and Ari Hentunen and Mikko Pihlatie and Jari Veps{\"a}l{\"a}inen and Mikaela Ranta and Prashant Singh and Tota, \{Sai Santhosh\}",

year = "2026",

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AU - Skeel, Erik

AU - Hentunen, Ari

AU - Pihlatie, Mikko

AU - Vepsäläinen, Jari

AU - Ranta, Mikaela

AU - Singh, Prashant

AU - Tota, Sai Santhosh

PY - 2026/4/28

Y1 - 2026/4/28

N2 - Decarbonizing heavy-duty road freight transportation requires efficient energy management in zero-emission powertrains. This study investigates energy management strategies (EMSs) for a heavy-duty Fuel Cell Plug-in Hybrid Electric Vehicle (FC-PHEV). Rather than the typical charge-sustaining operation, these strategies are designed for charge-depleting operation, in which each route begins with a charged battery and ends at a lower state of charge (SOC), leveraging the vehicle’s plug-in capability. The EMSs are evaluated primarily in terms of energy consumption, while battery C-rate and fuel cell ramp rate are used as simple stress indicators for comparative analysis. A backward-facing vehicle model is developed to test several EMSs, including both optimization- and rule-based strategies. The Equivalent Consumption Minimization Strategy (ECMS) emerged as a promising option, motivating further testing with a forward-facing model and additional drive cycles. The simulation results show that ECMS consumed only 1.1% more energy than the global optimal solution found by Pontryagin’s Minimum Principle (PMP) and 7.5% less energy than a simple rule-based strategy, on average across five drive cycles. These results show that ECMS can be effective for a heavy-duty FC-PHEV operating in charge-depleting mode, extending its demonstrated applicability beyond charge-sustaining and light-duty vehicles.

AB - Decarbonizing heavy-duty road freight transportation requires efficient energy management in zero-emission powertrains. This study investigates energy management strategies (EMSs) for a heavy-duty Fuel Cell Plug-in Hybrid Electric Vehicle (FC-PHEV). Rather than the typical charge-sustaining operation, these strategies are designed for charge-depleting operation, in which each route begins with a charged battery and ends at a lower state of charge (SOC), leveraging the vehicle’s plug-in capability. The EMSs are evaluated primarily in terms of energy consumption, while battery C-rate and fuel cell ramp rate are used as simple stress indicators for comparative analysis. A backward-facing vehicle model is developed to test several EMSs, including both optimization- and rule-based strategies. The Equivalent Consumption Minimization Strategy (ECMS) emerged as a promising option, motivating further testing with a forward-facing model and additional drive cycles. The simulation results show that ECMS consumed only 1.1% more energy than the global optimal solution found by Pontryagin’s Minimum Principle (PMP) and 7.5% less energy than a simple rule-based strategy, on average across five drive cycles. These results show that ECMS can be effective for a heavy-duty FC-PHEV operating in charge-depleting mode, extending its demonstrated applicability beyond charge-sustaining and light-duty vehicles.

U2 - 10.3390/wevj17050233

DO - 10.3390/wevj17050233

M3 - Article

SN - 2032-6653

VL - 17

JO - World Electric Vehicle Journal

JF - World Electric Vehicle Journal

IS - 5

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Energy Management for a Fuel Cell Plug-In Hybrid Heavy-Duty Vehicle

Abstract

Funding

UN SDGs

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Projects

THERMAZEV: Thermal management for real zero-emission vehicles

ESCALATE: Powering EU Net Zero Future by Escalating Zero Emission HDVs and Logistic Intelligence

REPowerEU at VTT

Cite this