Environmental Effects of Electromobility in a Sustainable Urban Public Transport

Pietrzak, Krystian; Pietrzak, Oliwia

doi:10.3390/su12031052

Cited by 98 publications

(75 citation statements)

References 72 publications

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“…SoC max = 0.9; E max = SoC max * Capacity installed (MWh). (10) and stored energy limitation in the proposed BESS FCR model are determined as follows:…”

Section: Nmc Battery Cell Parametersmentioning

confidence: 99%

“…According to the International Energy Agency, at the end of 2019, over 1.5 million electric vehicles (EVs) (including battery electric vehicles (BEVs) and plug-in hybrid electric vehicles (PHEVs)) were registered in the EU. [9] The total number of registered EVs in the EU is expected to accelerate its growth due to the falling prices of battery technology (battery cost breakdown) and government financial subsidies and support [10]. According to estimates of the cumulative number of EVs based on optimal development, EU countries will have more than 10 million electric vehicles by 2030 [11].…”

Section: Introductionmentioning

confidence: 99%

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Second Life Batteries Used in Energy Storage for Frequency Containment Reserve Service

Janota¹,

Králík²,

Knápek³

2020

Energies

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The new Li-ion battery systems used in electric vehicles have an average capacity of 50 kWh and are expected to be discarded when they reach approximately 80% of their initial capacity, because they are considered to no longer be sufficient for traction purposes. Based on the official national future development scenarios and subsequent mathematical modeling of the number of electric vehicles (EVs), up to 400 GWh of storage capacity in discharged batteries will be available on the EU market by 2035. Therefore, since the batteries still have a considerable capacity after the end of their first life, they could be used in many stationary applications during their second life, such as support for renewables, flexibility, energy arbitrage, peak shaving, etc. Due to the high output power achieved in a short time, one of the most promising applications of these batteries are ancillary services. The study assesses the economic efficiency of the used batteries and presents several main scenarios depending on the likely future development of the interconnected EU regulatory energy market. The final results indicate that the best results of second-life batteries utilization lie in the provision of Frequency Containment Reserve Service, both from a technical and economic point of view. The internal rate of return fluctuates from 8% to 21% in the realistic scenario, and it supports the idea that such systems might be able to be in operation without any direct financial subsidies.

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“…SoC max = 0.9; E max = SoC max * Capacity installed (MWh). (10) and stored energy limitation in the proposed BESS FCR model are determined as follows:…”

Section: Nmc Battery Cell Parametersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Second Life Batteries Used in Energy Storage for Frequency Containment Reserve Service

Janota¹,

Králík²,

Knápek³

2020

Energies

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“…Otherwise, [96] describes the challenges and assessment of electric vehicles integration, with a comprehensive analysis of political, economic, social, technical, legislative and environmental aspects and rigorously assesses achievability of the EV integration. Thus, electric mobility contributes to the independence of imported fossil energies, constitutes a lever for the integration of RE in the energy mix because partial electrification of transport encourages the installation of (decentralized) renewable energy production units, storage (V2G: vehicle to grid) and the valorization of surpluses for the production of hydrogen [97] , [98] .…”

Section: Key Elements For Successful Transformation Of the Power Systmentioning

confidence: 99%

Towards a large-scale integration of renewable energies in Morocco

Boulakhbar

Lebrouhi

Kousksou

et al. 2020

Journal of Energy Storage

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“…The automotive industry has faced a paradigm shift towards electromobility in recent years to reduce greenhouse gas emissions, air pollution, and dependence on fossil fuels [1]. Therefore, Lithium-ion (Li-ion) battery storage systems have undergone a substantial growth in popularity, as they play an indispensable role in emerging electric vehicles (EVs) [2,3].…”

Section: Introductionmentioning

confidence: 99%

Calibration Optimization Methodology for Lithium-Ion Battery Pack Model for Electric Vehicles in Mining Applications

et al. 2020

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Large-scale introduction of electric vehicles (EVs) to the market sets outstanding requirements for battery performance to extend vehicle driving range, prolong battery service life, and reduce battery costs. There is a growing need to accurately and robustly model the performance of both individual cells and their aggregated behavior when integrated into battery packs. This paper presents a novel methodology for Lithium-ion (Li-ion) battery pack simulations under actual operating conditions of an electric mining vehicle. The validated electrochemical-thermal models of Li-ion battery cells are scaled up into battery modules to emulate cell-to-cell variations within the battery pack while considering the random variability of battery cells, as well as electrical topology and thermal management of the pack. The performance of the battery pack model is evaluated using transient experimental data for the pack operating conditions within the mining environment. The simulation results show that the relative root mean square error for the voltage prediction is 0.7–1.7% and for the battery pack temperature 2–12%. The proposed methodology is general and it can be applied to other battery chemistries and electric vehicle types to perform multi-objective optimization to predict the performance of large battery packs.

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Environmental Effects of Electromobility in a Sustainable Urban Public Transport

Cited by 98 publications

References 72 publications

Second Life Batteries Used in Energy Storage for Frequency Containment Reserve Service

Second Life Batteries Used in Energy Storage for Frequency Containment Reserve Service

Towards a large-scale integration of renewable energies in Morocco

Calibration Optimization Methodology for Lithium-Ion Battery Pack Model for Electric Vehicles in Mining Applications

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