On-Board Energy Storage Devices with Supercapacitors for Metro Trains—Case Study Analysis of Application Effectiveness

Radu, Petru Valentin; Szeląg, A.; Steczek, Marcin

doi:10.3390/en12071291

Cited by 31 publications

(27 citation statements)

References 24 publications

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“…Finally, it allows the vehicle to have catenary -free driving [62], [157] Some research studies on onboard ESSs found that an energy saving about 14% to 34% could be achieved when onboard ESSs are deployed in urban railway applications [158], [159].…”

Section: Onboard Energy Storage System Modementioning

confidence: 99%

Review of Energy Storage Systems in Regenerative Braking Energy Recovery in DC Electrified Urban Railway Systems: Converter Topologies, Control Methods & Future Prospects

Sadiq¹

2021

Preprint

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<p>Electrified urban railway systems are large consumers of energy in urban areas and thus, there is a need for energy saving measures in this transportation sector. Recuperation of train’s regenerative braking energy (RBE) is one of the best ways for attaining high levels of energy efficiency in this area. Energy Storage Systems (ESSs) prove to be the most practical and viable solution for maximizing the RBE utilization in urban railway systems. In the existing related reviews of ESSs, few papers covered the review of ESS technologies or converter interface. However, a comprehensive review is needed in this regard. This paper discusses an overview of urban railway electrification, and detail review for the three ESS components – ESS Technologies, Bidirectional DC-DC Converters (BDCs), and Controller Unit. This study concludes that among the storage technologies, supercapacitor ESS appears to be the most suitable followed by Lithium-ion batteries and flywheels. For BDC, cascaded BDC is the most suitable followed by dual active bridge. For control methods, fuzzy logic and artificial intelligent are recommended among other control strategies. Thus, the key contribution of this paper is the comprehensive review and analyses of the ESS’s components in the recovery of RBE in urban railways. </p>

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Section: Onboard Energy Storage System Modementioning

confidence: 99%

Review of Energy Storage Systems in Regenerative Braking Energy Recovery in DC Electrified Urban Railway Systems: Converter Topologies, Control Methods & Future Prospects

Sadiq¹

2021

Preprint

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“…The ESS can be located outside the vehicle (wayside energy storage) or inside the vehicle as a mobile energy storage system (onboard energy storage). The work, [6], deals with the optimal positioning and sizing of a stationary ESS, while the studies in [7] analyze the economic and energetic viability of installing an ESS into a rail vehicle. The ESS usually consists of battery or supercapacitor modules; in rare cases, flywheels are also used [8].…”

Section: Introductionmentioning

confidence: 99%

Route Profile Dependent Tram Regenerative Braking Algorithm with Reduced Impact on the Supply Network

et al. 2021

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Electric trams are one of the standard forms of public transport. They are characterized by large amounts of electric current and electric current gradient from the power grid, especially during acceleration. For this reason, a regenerative braking system is considered with the aim of reducing electric current peaks and increasing energy efficiency by reducing the total energy consumption of the power grid. A supercapacitor module is used as a storage device for storing and utilizing the braking energy. The supercapacitor module and the power grid constitute a hybrid energy system, for which a control algorithm has been developed. The control algorithm takes into account the influence of the elevation profile and the slope of the vehicle route in storing and using the braking energy. The operation of the algorithm was simulated and analyzed using the MATLAB/Simulink software package for tram lines with different elevation profiles.

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“…Supercapacitors (SCs) and batteries offer high efficiency and a high speed of access to electrical energy. They are, therefore, an ideal complement to the FC in hybrid electric locomotives [10–13].…”

Section: Introductionmentioning

confidence: 99%

“…Compared with other approaches, these strategies are intuitive and easier to implement. Many research studies propose rule‐based methodologies to determine the power distribution in hybrid trains [13, 28–30].…”

Section: Introductionmentioning

confidence: 99%

Energy management strategy to optimise regenerative braking in a hybrid dual‐mode locomotive

Mendoza

Solano

Boulon

2020

IET Electrical Systems in Transportation

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On-Board Energy Storage Devices with Supercapacitors for Metro Trains—Case Study Analysis of Application Effectiveness

Cited by 31 publications

References 24 publications

Review of Energy Storage Systems in Regenerative Braking Energy Recovery in DC Electrified Urban Railway Systems: Converter Topologies, Control Methods & Future Prospects

Review of Energy Storage Systems in Regenerative Braking Energy Recovery in DC Electrified Urban Railway Systems: Converter Topologies, Control Methods & Future Prospects

Route Profile Dependent Tram Regenerative Braking Algorithm with Reduced Impact on the Supply Network

Energy management strategy to optimise regenerative braking in a hybrid dual‐mode locomotive

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