Recent trends in power electronics applications as solutions in electric railways

Hayashiya, Hitoshi; Kondo, Keiichiro

doi:10.1002/tee.23121

Cited by 27 publications

(22 citation statements)

References 42 publications

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“…In the past, some passive solutions helped to alleviate these issues but their performance was dependent on different operation parameters and has poor dynamics. Then, the use of power electronics based converters for power quality increasing in railway systems has entered into the domain and is continuously increasing [11][12][13]. Their purpose is quite large and addresses different power quality issues in railway systems: transformer losses, catenary voltage stability, substation active power balancing, peak shaving, three-phase current balancing, reactive power compensation [13][14][15].…”

Section: Literature Reviewmentioning

confidence: 99%

“…Then, the use of power electronics based converters for power quality increasing in railway systems has entered into the domain and is continuously increasing [11][12][13]. Their purpose is quite large and addresses different power quality issues in railway systems: transformer losses, catenary voltage stability, substation active power balancing, peak shaving, three-phase current balancing, reactive power compensation [13][14][15]. It should be mentioned that the static frequency converter (SFC) system is a kind of ''one fits all'' regarding all the referred power quality issues but this system is a stand-alone solution, interesting for new lines, [12,[16][17][18].…”

Section: Literature Reviewmentioning

confidence: 99%

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Traction power substation balance and losses estimation in AC railways using a power transfer device through Monte Carlo analysis

Morais

Martins

2022

Rail. Eng. Science

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The high dynamic power requirements present in modern railway transportation systems raise research challenges for an optimal operation of railway electrification. This paper presents a Monte Carlo analysis on the application of a power transfer device installed in the neutral zone and exchanging active power between two sections. The main analyzed parameters are the active power balance in the two neighbor traction power substations and the system power losses. A simulation framework is presented to comprise the desired analysis and a universe of randomly distributed scenarios are tested to evaluate the effectiveness of the power transfer device system. The results show that the density of trains and the relative branch length of a traction power substation should be considered in the evaluation phase of the best place to install a power transfer device, towards the reduction of the operational power losses, while maintaining the two substations balanced in terms of active power.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Literature Reviewmentioning

confidence: 99%

Traction power substation balance and losses estimation in AC railways using a power transfer device through Monte Carlo analysis

Morais

Martins

2022

Rail. Eng. Science

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“…For instance, when dc traction machines are utilized, dc-dc converters are crucial to adjust the dc voltage values. On the other side, dc-ac converters are indispensable to drive the ac electric machines by changing the voltage frequency and amplitude, known as variable voltage variable frequency drive [270,271]. Future converter technologies are likely to utilize SiC devices for more efficient traction systems, besides the benefits of higher temperature operation capability and the possibility of manufacturing smaller and lighter power converters without transformers.…”

Section: L2 L1mentioning

confidence: 99%

“…Future converter technologies are likely to utilize SiC devices for more efficient traction systems, besides the benefits of higher temperature operation capability and the possibility of manufacturing smaller and lighter power converters without transformers. However, there are still issues to be solved in terms of both costs and technology, provided that SiC devices still have poor global ease of procurement and high costs [271]. The auxiliary converters are used to supply the train auxiliary loads.…”

Section: L2 L1mentioning

confidence: 99%

A Review on Power Electronics Technologies for Electric Mobility

et al. 2020

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Concerns about greenhouse gas emissions are a key topic addressed by modern societies worldwide. As a contribution to mitigate such effects caused by the transportation sector, the full adoption of electric mobility is increasingly being seen as the main alternative to conventional internal combustion engine (ICE) vehicles, which is supported by positive industry indicators, despite some identified hurdles. For such objective, power electronics technologies play an essential role and can be contextualized in different purposes to support the full adoption of electric mobility, including on-board and off-board battery charging systems, inductive wireless charging systems, unified traction and charging systems, new topologies with innovative operation modes for supporting the electrical power grid, and innovative solutions for electrified railways. Embracing all of these aspects, this paper presents a review on power electronics technologies for electric mobility where some of the main technologies and power electronics topologies are presented and explained. In order to address a broad scope of technologies, this paper covers road vehicles, lightweight vehicles and railway vehicles, among other electric vehicles.

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“…Recently, new power electronics devices and converter topologies allowed the development of advanced versions of the Steinmetz compensation circuit, either as single converters [6][7][8][9] or hybrid solutions [10,11]. Thyristor-based or IGBT-based these compensators are active balancers since they do not behave as variable equivalent impedances in parallel with the point of common coupling but, instead, they act as variable current sources according to the operation point of the railway load.…”

Section: Introductionmentioning

confidence: 99%

Voltage Unbalance, Power Factor and Losses Optimization in Electrified Railways Using an Electronic Balancer

et al. 2021

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Unbalanced currents, low power factor and high losses contribute to increasing the bill infrastructure managers must pay to the TSO/DSO operator that supplies electric energy to the railway system. Additionally, if regenerative energy coming from braking regimes is not allowed to be injected into the grid or even is penalized when it occurs, then the optimization of those parameters must be pursued. One of the possible measures that can be taken to counteract those phenomena is the installation of electronic balancers in heavy loaded substations in order to optimize the interface to the three-phase electric grid. This paper shows the benefit of such use taking examples from real conditions and realistic simulations assumed equivalent to field measurements.

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Recent trends in power electronics applications as solutions in electric railways

Cited by 27 publications

References 42 publications

Traction power substation balance and losses estimation in AC railways using a power transfer device through Monte Carlo analysis

Traction power substation balance and losses estimation in AC railways using a power transfer device through Monte Carlo analysis

A Review on Power Electronics Technologies for Electric Mobility

Voltage Unbalance, Power Factor and Losses Optimization in Electrified Railways Using an Electronic Balancer

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