Application of dynamic programming to optimal energy management of grid-independent hybrid railcars

Sorrentino, Marco; Agbli, Kréhi Serge; Hissel, Daniel; Chauvet, Frédéric; Letrouvé, Tony

doi:10.1177/0954409720920080

Cited by 10 publications

(7 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The resulting operation is characterized by frequent switches in the power split factor, what further complicates its on-line implementation. Therefore, DP is commonly used just as baseline for benchmarking other EMSs [22]. The optimization problem is based on the following cost function:…”

Section: ) Frb -Fuzzy Logic-based Strategy (Fl)mentioning

confidence: 99%

“…In Global Optimization (GOP) strategies, the optimization is developed off-line based on a pre-defined or predicted drive cycle, while in Real Time Optimization (RTOP) strategies the optimization is developed on-line. Proposed GOP strategies for hybrid diesel railway vehicles include approaches based on dynamic programming [18], [22], Pontryagin's minimum principle [17], non-linear programming [23] and genetic algorithm [24]. RTOP strategies such as equivalent consumption minimization or model predictive control have been proposed for other hybrid railway topologies such as FC vehicles [25], [26].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Li-Ion Battery-Based Hybrid Diesel-Electric Railway Vehicle: In-Depth Life Cycle Cost Analysis

Olmos

Lopez

Larrea

et al. 2022

IEEE Trans. Veh. Technol.

View full text Add to dashboard Cite

In this study, the life cycle costs of railway projects involving hybrid diesel-electric vehicles are analysed. Specifically, the analysis focuses on the comparison of 3 lithium-ion battery technologies (NMC, LTO and LFP) and 8 energy management strategies (including rule-based and optimization-based strategies). In order to develop this analysis, a methodology that returns the life cycle cost of each proposed case is presented. The methodology includes the optimization of the diesel generator and lithium-ion battery sizing. A scenario based on a real railway line is introduced, and the obtained results are compared to a traditional diesel-electric railway vehicle to develop a technoeconomical discussion. The best lithium-ion battery technologies are found to be LTO and NMC, and the most appropriated strategy a state-machine controller optimised by a genetic algorithm approach. The best case obtains a life cycle cost reduction of the 4.0% and diesel savings of the 13.7% compared to a traditional diesel-electric railway vehicle. The proposed analysis is claimed to be potentially helpful for the cost-optimal design and operation definition of powertrains for hybrid railway vehicles.

show abstract

Section: ) Frb -Fuzzy Logic-based Strategy (Fl)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Li-Ion Battery-Based Hybrid Diesel-Electric Railway Vehicle: In-Depth Life Cycle Cost Analysis

Olmos

Lopez

Larrea

et al. 2022

IEEE Trans. Veh. Technol.

View full text Add to dashboard Cite

show abstract

“…Their aim is to minimize energy consumption by managing the power flows from different energy sources in the system. Dynamic programming (DP), as a global optimization method, is widely used in EMS optimization for hybrid railway vehicles [37][38][39]. It was also used in deriving a fuel-optimal combined driving and energy management strategy [40].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Hybrid and Plug-In Hybrid Alternative Propulsion Systems for Regional Diesel-Electric Multiple Unit Trains

2021

View full text Add to dashboard Cite

This paper presents a simulation-based analysis of hybrid and plug-in hybrid propulsion system concepts for diesel-electric multiple unit regional railway vehicles. These alternative concepts primarily aim to remove emissions in terminal stops with longer stabling periods, with additional benefits reflected in the reduction of overall fuel consumption, produced emissions, and monetary costs. The alternative systems behavior is modeled using a backward-looking quasi-static simulation approach, with the implemented energy management strategy based on a finite state machine control. A comparative assessment of alternative propulsion systems is carried out in a case study of a selected regional railway line operated by Arriva, the largest regional railway undertaking in the Netherlands. The conversion of a standard diesel-electric multiple unit vehicle, currently operating on the network, demonstrated a potential GHG reduction of 9.43–56.92% and an energy cost reduction of 9.69–55.46%, depending on the type of service (express or stopping), energy storage technology selection (lithium-ion battery or double-layer capacitor), electricity production (green or grey electricity), and charging facilities configuration (charging in terminal stations with or without additional charging possibility during short intermediate stops) used. As part of a bigger project aiming to identify optimal transitional solutions towards emissions-free trains, the outcomes of this study will help in the future fleet planning.

show abstract

“…Given that such vehicles operate on fixed schedules, their duty cycle can be derived from vehicle and route data. [5][6][7] However, switcher locomotives do not operate on fixed schedules, and therefore require the synthesis of a driving cycle for power source sizing, [8][9][10][11][12] and energy management. 8,10 To that end, dieselelectric locomotives would typically be instrumented to record engine-generator power which would be used for power source selection and sizing.…”

Section: Introductionmentioning

confidence: 99%

The development of a representative multidimensional transient duty cycle for in-service switcher locomotives

Hegazi

Hoffrichter²,

Andrews

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part F:

View full text Add to dashboard Cite

Switcher locomotives operate in railway yards where they shunt railcars and assemble trains. Shunting railcars requires frequent aggressive acceleration and deceleration events in order for the locomotive to push or pull railcars onto specific tracks. As a result, switcher locomotives rarely sustain tractive power for any significant period of time. Given that all switchers in North America rely on diesel-electric propulsion; the result is rapid and frequent transitions in engine power leading to a very low engine efficiency and high levels of emissions. Any attempt to quantify or remedy these issues will face a lack of a representative profile or test cycle. A locomotive duty cycle is a breakdown of time spent at each power level of the locomotive’s engine. A major drawback of current duty cycles is that they only account for steady power. Such cycles are not representative of real switcher locomotive operation. This paper presents a real-world transient duty cycle for switcher locomotives that accounts for the rapid power transitions and is argued to be more statistically representative of actual operations. The methodology adopted relies on real-time data collection, microtrip based trip segmentation, and a finite mixture model-based clustering algorithm. Measurements were collected on a EMD 16-645 GP9 locomotive. The duty cycle developed herein is representative of switching operations in Southern Railway of British Columbia’s New Westminster Yard as an example of the methodology which can be repeated in other cases as well.

show abstract

Application of dynamic programming to optimal energy management of grid-independent hybrid railcars

Cited by 10 publications

References 31 publications

Li-Ion Battery-Based Hybrid Diesel-Electric Railway Vehicle: In-Depth Life Cycle Cost Analysis

Li-Ion Battery-Based Hybrid Diesel-Electric Railway Vehicle: In-Depth Life Cycle Cost Analysis

Analysis of Hybrid and Plug-In Hybrid Alternative Propulsion Systems for Regional Diesel-Electric Multiple Unit Trains

The development of a representative multidimensional transient duty cycle for in-service switcher locomotives

Contact Info

Product

Resources

About