Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System

George Leoutsakos; Alexandros Deloukas; Kanellina Giannakopoulou; Maria Zarkadoula; Dimitris Kyriazidis; Astrid Bensmann

doi:10.1007/978-3-031-23721-8_4

Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System

George Leoutsakos, Alexandros Deloukas^*, Kanellina Giannakopoulou, Maria Zarkadoula, Dimitris Kyriazidis, Astrid Bensmann

^*Corresponding author for this work

Section Electrical Energy Storage Systems

Research output: Chapter in book/report/conference proceeding › Contribution to book/anthology › Research › peer review

Abstract

The utilization of excess energy produced through vehicle movements stands in the center of efficiency measures in the transport sector. In case of electric trains, the excess energy of vehicle regenerative braking is mostly wasted as heat. Instead of an instantaneous waste, a later re-use of this energy requests the adoption of an electric storage system. The paper describes real data obtained through on-site and train on-board measurement schemes and a methodology to achieve metro system energy savings redirecting unused energy produced from braking metro trains to the metro station grid consumption. An emphasis is on cost/returns analysis and environmental benefits of the storage system. The Hybrid Energy Storage System (HESS) design developed for the Athens Metro combines efficiently the higher power density and (dis)charging cycles of supercapacitors (coping the high frequency of train stops producing energy) with the superior energy density of batteries (matching a slower release and a longer energy consumption time of stations’ current drain). A smart energy management and control strategy allows upon demand for an internal energy transfer between both storage technologies. So far, single-technology, onboard or wayside storage systems servicing mainly the traction of accelerating trains were available. The novelty here is the dual-technology HESS, located at stations servicing the energy demand of the latter. Preliminary results confirm the feasibility of the energy saving concept indicating a large potential for the MetroHESS reuse of 5000–6000 kWh/day per rectifier substation of otherwise unused braking energy of a metro line and a subsequent s sizing of the stationary HESS is performed. About 30% of the braking energy accrued can be reused through the MetroHESS to cover about 90% of the station energy demand while the residual braking energy will be dissipated in the train braking resistors. An implementation of the stationary storage system to Line 2&3 rectifier substations would cost 17 mi.€, saving on an annual base about 4 mi.€ electricity expenses for the operator as well as 8.600 tons CO₂ for the sake of the community.

Original language	English
Title of host publication	Smart Energy for Smart Transport
Subtitle of host publication	Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece
Editors	Eftihia G. Nathanail, Nikolaos Gavanas, Giannis Adamos
Publisher	Springer Nature
Pages	50-62
Number of pages	13
ISBN (Electronic)	9783031237218
ISBN (Print)	9783031237201
DOIs	https://doi.org/10.1007/978-3-031-23721-8_4
Publication status	Published - 11 Mar 2023
Event	Conference on Sustainable Urban Mobility: Smart Energy for Smart Transport - Skiathos Island, Greece Duration: 31 Aug 2022 → 2 Sept 2022

Publication series

Name	Lecture Notes in Intelligent Transportation and Infrastructure
ISSN (Print)	2523-3440
ISSN (Electronic)	2523-3459

Conference

Conference	Conference on Sustainable Urban Mobility
Country/Territory	Greece
City	Skiathos Island
Period	31 Aug 2022 → 2 Sept 2022

UN Sustainable Development Goals (SDGs)

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

SDG 7 Affordable and Clean Energy

Keywords

Electric vehicle regenerative braking
Metro energy savings
Smart hybrid energy storage system
Station energy loads

ASJC Scopus subject areas

Computer Science Applications
Automotive Engineering
Control and Systems Engineering
Transportation

Access to Document

10.1007/978-3-031-23721-8_4

Cite this

Leoutsakos, G., Deloukas, A., Giannakopoulou, K., Zarkadoula, M., Kyriazidis, D., & Bensmann, A. (2023). Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System. In E. G. Nathanail, N. Gavanas, & G. Adamos (Eds.), Smart Energy for Smart Transport: Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece (pp. 50-62). (Lecture Notes in Intelligent Transportation and Infrastructure). Springer Nature. https://doi.org/10.1007/978-3-031-23721-8_4

Leoutsakos, George ; Deloukas, Alexandros ; Giannakopoulou, Kanellina et al. / Metro Braking Energy for Station Electric Loads : The Business Case of a Smart Hybrid Storage System. Smart Energy for Smart Transport: Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece. editor / Eftihia G. Nathanail ; Nikolaos Gavanas ; Giannis Adamos. Springer Nature, 2023. pp. 50-62 (Lecture Notes in Intelligent Transportation and Infrastructure).

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abstract = "The utilization of excess energy produced through vehicle movements stands in the center of efficiency measures in the transport sector. In case of electric trains, the excess energy of vehicle regenerative braking is mostly wasted as heat. Instead of an instantaneous waste, a later re-use of this energy requests the adoption of an electric storage system. The paper describes real data obtained through on-site and train on-board measurement schemes and a methodology to achieve metro system energy savings redirecting unused energy produced from braking metro trains to the metro station grid consumption. An emphasis is on cost/returns analysis and environmental benefits of the storage system. The Hybrid Energy Storage System (HESS) design developed for the Athens Metro combines efficiently the higher power density and (dis)charging cycles of supercapacitors (coping the high frequency of train stops producing energy) with the superior energy density of batteries (matching a slower release and a longer energy consumption time of stations{\textquoteright} current drain). A smart energy management and control strategy allows upon demand for an internal energy transfer between both storage technologies. So far, single-technology, onboard or wayside storage systems servicing mainly the traction of accelerating trains were available. The novelty here is the dual-technology HESS, located at stations servicing the energy demand of the latter. Preliminary results confirm the feasibility of the energy saving concept indicating a large potential for the MetroHESS reuse of 5000–6000 kWh/day per rectifier substation of otherwise unused braking energy of a metro line and a subsequent s sizing of the stationary HESS is performed. About 30% of the braking energy accrued can be reused through the MetroHESS to cover about 90% of the station energy demand while the residual braking energy will be dissipated in the train braking resistors. An implementation of the stationary storage system to Line 2&3 rectifier substations would cost 17 mi.€, saving on an annual base about 4 mi.€ electricity expenses for the operator as well as 8.600 tons CO2 for the sake of the community.",

keywords = "Electric vehicle regenerative braking, Metro energy savings, Smart hybrid energy storage system, Station energy loads",

author = "George Leoutsakos and Alexandros Deloukas and Kanellina Giannakopoulou and Maria Zarkadoula and Dimitris Kyriazidis and Astrid Bensmann",

note = "Funding Information: The present study was conducted in the framework of the MetroHESS research project of the “Bilateral and Multilateral Cooperation between Greece and Germany”, co-financed and funded by the German Federal Ministry of Education and Research (BMBF) with funding code 03SF0560A, by the European Regional Development Fund (ERDF) and by the Greek National Resources through OP: Competitiveness, Entrepreneurship & Innovation (EPANEK) with funding code T2DGE-0327. The authors would like to thank the funding authorities, the Athens Metro project Owner Attiko Metro SA, the Athens Metro Operations company (STASY S.A.), the project coordinator CRES in Athens, the Leibniz University of Hannover (LUH) and the Stercom Power Solutions GmbH company (Stercom) who are the MetroHESS project partners. The last partner (Stercom) is the one co-configuring and assembling the Hybrid Energy Saving System demonstrator.; Conference on Sustainable Urban Mobility ; Conference date: 31-08-2022 Through 02-09-2022",

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day = "11",

doi = "10.1007/978-3-031-23721-8_4",

language = "English",

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series = "Lecture Notes in Intelligent Transportation and Infrastructure",

publisher = "Springer Nature",

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Leoutsakos, G, Deloukas, A, Giannakopoulou, K, Zarkadoula, M, Kyriazidis, D & Bensmann, A 2023, Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System. in EG Nathanail, N Gavanas & G Adamos (eds), Smart Energy for Smart Transport: Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece. Lecture Notes in Intelligent Transportation and Infrastructure, Springer Nature, pp. 50-62, Conference on Sustainable Urban Mobility, Skiathos Island, Greece, 31 Aug 2022. https://doi.org/10.1007/978-3-031-23721-8_4

Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System. / Leoutsakos, George; Deloukas, Alexandros; Giannakopoulou, Kanellina et al.
Smart Energy for Smart Transport: Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece. ed. / Eftihia G. Nathanail; Nikolaos Gavanas; Giannis Adamos. Springer Nature, 2023. p. 50-62 (Lecture Notes in Intelligent Transportation and Infrastructure).

Research output: Chapter in book/report/conference proceeding › Contribution to book/anthology › Research › peer review

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AU - Kyriazidis, Dimitris

AU - Bensmann, Astrid

N1 - Funding Information: The present study was conducted in the framework of the MetroHESS research project of the “Bilateral and Multilateral Cooperation between Greece and Germany”, co-financed and funded by the German Federal Ministry of Education and Research (BMBF) with funding code 03SF0560A, by the European Regional Development Fund (ERDF) and by the Greek National Resources through OP: Competitiveness, Entrepreneurship & Innovation (EPANEK) with funding code T2DGE-0327. The authors would like to thank the funding authorities, the Athens Metro project Owner Attiko Metro SA, the Athens Metro Operations company (STASY S.A.), the project coordinator CRES in Athens, the Leibniz University of Hannover (LUH) and the Stercom Power Solutions GmbH company (Stercom) who are the MetroHESS project partners. The last partner (Stercom) is the one co-configuring and assembling the Hybrid Energy Saving System demonstrator.

PY - 2023/3/11

Y1 - 2023/3/11

N2 - The utilization of excess energy produced through vehicle movements stands in the center of efficiency measures in the transport sector. In case of electric trains, the excess energy of vehicle regenerative braking is mostly wasted as heat. Instead of an instantaneous waste, a later re-use of this energy requests the adoption of an electric storage system. The paper describes real data obtained through on-site and train on-board measurement schemes and a methodology to achieve metro system energy savings redirecting unused energy produced from braking metro trains to the metro station grid consumption. An emphasis is on cost/returns analysis and environmental benefits of the storage system. The Hybrid Energy Storage System (HESS) design developed for the Athens Metro combines efficiently the higher power density and (dis)charging cycles of supercapacitors (coping the high frequency of train stops producing energy) with the superior energy density of batteries (matching a slower release and a longer energy consumption time of stations’ current drain). A smart energy management and control strategy allows upon demand for an internal energy transfer between both storage technologies. So far, single-technology, onboard or wayside storage systems servicing mainly the traction of accelerating trains were available. The novelty here is the dual-technology HESS, located at stations servicing the energy demand of the latter. Preliminary results confirm the feasibility of the energy saving concept indicating a large potential for the MetroHESS reuse of 5000–6000 kWh/day per rectifier substation of otherwise unused braking energy of a metro line and a subsequent s sizing of the stationary HESS is performed. About 30% of the braking energy accrued can be reused through the MetroHESS to cover about 90% of the station energy demand while the residual braking energy will be dissipated in the train braking resistors. An implementation of the stationary storage system to Line 2&3 rectifier substations would cost 17 mi.€, saving on an annual base about 4 mi.€ electricity expenses for the operator as well as 8.600 tons CO2 for the sake of the community.

AB - The utilization of excess energy produced through vehicle movements stands in the center of efficiency measures in the transport sector. In case of electric trains, the excess energy of vehicle regenerative braking is mostly wasted as heat. Instead of an instantaneous waste, a later re-use of this energy requests the adoption of an electric storage system. The paper describes real data obtained through on-site and train on-board measurement schemes and a methodology to achieve metro system energy savings redirecting unused energy produced from braking metro trains to the metro station grid consumption. An emphasis is on cost/returns analysis and environmental benefits of the storage system. The Hybrid Energy Storage System (HESS) design developed for the Athens Metro combines efficiently the higher power density and (dis)charging cycles of supercapacitors (coping the high frequency of train stops producing energy) with the superior energy density of batteries (matching a slower release and a longer energy consumption time of stations’ current drain). A smart energy management and control strategy allows upon demand for an internal energy transfer between both storage technologies. So far, single-technology, onboard or wayside storage systems servicing mainly the traction of accelerating trains were available. The novelty here is the dual-technology HESS, located at stations servicing the energy demand of the latter. Preliminary results confirm the feasibility of the energy saving concept indicating a large potential for the MetroHESS reuse of 5000–6000 kWh/day per rectifier substation of otherwise unused braking energy of a metro line and a subsequent s sizing of the stationary HESS is performed. About 30% of the braking energy accrued can be reused through the MetroHESS to cover about 90% of the station energy demand while the residual braking energy will be dissipated in the train braking resistors. An implementation of the stationary storage system to Line 2&3 rectifier substations would cost 17 mi.€, saving on an annual base about 4 mi.€ electricity expenses for the operator as well as 8.600 tons CO2 for the sake of the community.

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Leoutsakos G, Deloukas A, Giannakopoulou K, Zarkadoula M, Kyriazidis D, Bensmann A. Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System. In Nathanail EG, Gavanas N, Adamos G, editors, Smart Energy for Smart Transport: Proceedings of the 6th Conference on Sustainable Urban Mobility, CSUM2022, August 31-September 2, 2022, Skiathos Island, Greece. Springer Nature. 2023. p. 50-62. (Lecture Notes in Intelligent Transportation and Infrastructure). doi: 10.1007/978-3-031-23721-8_4

Metro Braking Energy for Station Electric Loads: The Business Case of a Smart Hybrid Storage System

Abstract

Publication series

Conference

UN Sustainable Development Goals (SDGs)

Keywords

ASJC Scopus subject areas

Access to Document

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Cite this