Integrated Approach for the Assessment of Strategies for the Decarbonization of Urban Traffic

Göhlich, Dietmar; Nagel, Kai; Syré, Anne Magdalene; Grahle, Alexander; Martins-Turner, Kai; Ewert, Ricardo; Jahn, Ricardo Miranda; Jefferies, Dominic

doi:10.3390/su13020839

Cited by 30 publications

(16 citation statements)

References 89 publications

(100 reference statements)

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“…In general, areas with high population density and a high vehicle per capita rate have a higher demand for electrical energy compared to sparsely populated areas with few vehicles per inhabitant [6,10,11]. The authors of [3,4,6,12] show that the electrical energy and power demand for charging BEVs differs depending on the time of the day and the type of the day In their research on decarbonisation of the urban traffic, the authors of [17] used the activity-based simulation framework MATSim [18,19] to analyse the effects of complete replacement of the current population of ICEVs with BEVs in urban regions. The authors focused on electrification of the entire transport system including private vehicles, the public transportation sector, and commercial and municipal traffic.…”

Section: Introductionmentioning

confidence: 99%

Methodology for Estimating the Spatial and Temporal Power Demand of Private Electric Vehicles for an Entire Urban Region Using Open Data

2021

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With continuous proliferation of private battery electric vehicles (BEVs) in urban regions, the demand for electrical energy and power is constantly increasing. Electrical grid infrastructure operators are facing the question of where and to what extent they need to expand their infrastructure in order to meet the additional demand. Therefore, the aim of this paper is to develop an activity-based mobility model that supports electrical grid operators in detecting and evaluating possible overloads within the electrical grid, deriving from the aforementioned electrification. We apply our model, which fully relies on open data, to the urban area of Berlin. In addition to a household travel survey, statistics on the population density, the degree of motorisation, and the household income in fine spatial resolution are key data sources for generation of the model. The results show that the spatial distribution of the BEV charging energy demand is highly heterogeneous. The demand per capita is higher in peripheral areas of the city, while the demand per m2 area is higher in the inner city. For reference areas, we analysed the temporal distribution of the BEV charging power demand, by assuming that the vehicles are solely charged at their residential district. We show that the households’ power demand peak in the evening coincide with the BEV power demand peak while the total power demand can increase up to 77.9%.

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Section: Introductionmentioning

confidence: 99%

Methodology for Estimating the Spatial and Temporal Power Demand of Private Electric Vehicles for an Entire Urban Region Using Open Data

2021

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“…To evaluate the economic impact for an e-moped sharing operator, a life cycle cost analysis in form of a total cost of ownership (TCO) is conducted according to the approach in [24]. The cost components and their values are based on literature research, real sharing operator data and well-founded calculations, while the trip data used for the TCO is generated by the sharing simulation.…”

Section: Total Cost Of Ownershipmentioning

confidence: 99%

Analysis of Electric Moped Scooter Sharing in Berlin: A Technical, Economic and Environmental Perspective

Wortmann¹,

Syré²,

Grahle³

et al. 2021

Preprint

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Electric moped scooter sharing services have recently experienced strong growth rates, particularly in Europe. Due to their compactness, environmental-friendliness and convenience, shared e-mopeds are suitable modes of transport in urban mobility to help reduce the environmental impact. However, its traffic-related, economic and environmental effects are merely represented in academic research. We used passenger car traffic data in Berlin generated by the multi-agent transport simulation framework MATSim to develop a python-based simulation, resembling an e-moped sharing system. Based on the results, a total cost of ownership and a life cycle assessment for fleet sizes of 2,500, 10,000 and 50,000 vehicles were conducted. The results indicate that a substantial part of all passenger car trips in Berlin can be substituted. The larger the fleet, the more and longer trips are replaced. Simultaneously, the efficiency in terms of fleet utilization decreases. The scenario with 10,000 e-mopeds offers the lowest total distance-based costs for sharing operators, whereas a fleet consisting of 2,500 vehicles exhibits the lowest environmental emissions per kilometer driven over the expected lifespan of a shared e-moped. Based on the renewable energy potential for 2050 forecasted by the German Federal Environment Agency, a significant overall decline in environmental impacts can be achieved.

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“…Such a comprehensive target provides new challenges from the extended system boundaries-sectoral, temporal and spatial. It is clear, however, that a multidimensional sustainability assessment of entire scenarios is also an important task if transformation pathways, which are sustainable in a broader sense, are to be developed [31][32][33][34]. A number of approaches to this have been developed and applied in the past: Life cycle assessment (LCA) is increasingly combined with energy system models (see [15] for more references).…”

Section: Introduction 1backgroundmentioning

confidence: 99%

Integrated Multidimensional Sustainability Assessment of Energy System Transformation Pathways

et al. 2021

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Sustainable development embraces a broad spectrum of social, economic and ecological aspects. Thus, a sustainable transformation process of energy systems is inevitably multidimensional and needs to go beyond climate impact and cost considerations. An approach for an integrated and interdisciplinary sustainability assessment of energy system transformation pathways is presented here. It first integrates energy system modeling with a multidimensional impact assessment that focuses on life cycle-based environmental and macroeconomic impacts. Then, stakeholders’ preferences with respect to defined sustainability indicators are inquired, which are finally integrated into a comparative scenario evaluation through a multi-criteria decision analysis (MCDA), all in one consistent assessment framework. As an illustrative example, this holistic approach is applied to the sustainability assessment of ten different transformation strategies for Germany. Applying multi-criteria decision analysis reveals that both ambitious (80%) and highly ambitious (95%) carbon reduction scenarios can achieve top sustainability ranks, depending on the underlying energy transformation pathways and respective scores in other sustainability dimensions. Furthermore, this research highlights an increasingly dominant contribution of energy systems’ upstream chains on total environmental impacts, reveals rather small differences in macroeconomic effects between different scenarios and identifies the transition among societal segments and climate impact minimization as the most important stakeholder preferences.

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Integrated Approach for the Assessment of Strategies for the Decarbonization of Urban Traffic

Cited by 30 publications

References 89 publications

Methodology for Estimating the Spatial and Temporal Power Demand of Private Electric Vehicles for an Entire Urban Region Using Open Data

Methodology for Estimating the Spatial and Temporal Power Demand of Private Electric Vehicles for an Entire Urban Region Using Open Data

Analysis of Electric Moped Scooter Sharing in Berlin: A Technical, Economic and Environmental Perspective

Integrated Multidimensional Sustainability Assessment of Energy System Transformation Pathways

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