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

Straub, Florian; Streppel, Simon; Göhlich, Dietmar

doi:10.3390/en14082081

Cited by 17 publications

(8 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Finally, in the residential zone, we assume the presence of a high density of private houses, with a comparatively low demand in the morning and a peak in the evening and early night hours. These assumptions are consistent with several studies regarding the spatial-temporal distribution of the charging demands observed in urban areas (see, e.g., Yi et al, 2020;Straub et al, 2021).…”

Section: Spatial and Temporal Charging Demand Generationsupporting

confidence: 91%

Incorporating time-dependent demand patterns in the optimal location of capacitated charging stations

Filippi¹,

Guastaroba²,

Peirano³

et al. 2023

Preprint

View full text Add to dashboard Cite

A massive use of electric vehicles is nowadays considered to be a key element of a sustainable transportation policy and the availability of charging stations is a crucial issue for their extensive use. Charging stations in an urban area have to be deployed in such a way that they can satisfy a demand that may dramatically vary in space and time. In this paper we present an optimization model for the location of charging stations that takes into account the main specific features of the problem, in particular the different charging technologies, and their associated service time, and the fact that the demand depends on space and time. To measure the importance of incorporating the time dependence in an optimization model, we also present a simpler model that extends a classical location model and does not include the temporal dimension. A worst-case analysis and extensive computational experiments show that ignoring the temporal dimension of the problem may lead to a substantial amount of unsatisfied demand.

show abstract

Section: Spatial and Temporal Charging Demand Generationsupporting

confidence: 91%

Incorporating time-dependent demand patterns in the optimal location of capacitated charging stations

Filippi¹,

Guastaroba²,

Peirano³

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…E-mobility traffic simulations, mostly in the form of activity-based models, are commonly used for this purpose [5][6][7][8]. In activity-based models, individual full-day travel schedules are generated for all persons or vehicles within the considered geographical area.…”

Section: Global Warming and E-mobility Traffic Simulations To Estimate The Charging Demand Of Bevsmentioning

confidence: 99%

“…Based on these partial results, it is possible to estimate the spatial distribution of the charging energy and power demand that arises when the individuals solely charge their BEVs at home. This approach has been demonstrated in [5] for the urban area of Berlin, Germany, and its 448 sub-districts. However, these results need further refinement as they neglect the fact that vehicles do not always charge at home but can also charge at, e.g., work and shopping locations.…”

Section: Novel Research Approach For Estimating the Charging Demand Of Bevsmentioning

confidence: 99%

“…Since the car-access attractiveness of the districts is determined solely for shopping and work trips, vehicle routing can only determine the locations for shopping and work activities. However, in addition to the places of residence, these are the locations with the highest charging potential, as they have the highest average car idle times in Berlin (places of residence: 20.9 h per day, workplaces: 1.7 h and shopping locations: 0.1 h) [5].…”

Section: Literature Review and Research Gap Filled By This Papermentioning

confidence: 99%

See 1 more Smart Citation

Car-Access Attractiveness of Urban Districts Regarding Shopping and Working Trips for Usage in E-Mobility Traffic Simulations

2021

Self Cite

View full text Add to dashboard Cite

With the continuous proliferation of private battery electric vehicles, the demand for electrical energy and power is constantly increasing. As a result, the electrical grid may need to be expanded. To plan for such expansion, information about the spatial distribution of the energy demand is necessary. This can be determined from e-mobility traffic simulations, where travel schedules of individuals are combined with an attractiveness rating of locations to estimate traffic flows. Typically, attractiveness is determined from the “size” of locations (e.g., number of employees or sales area), which is applicable when all modes of transportation are considered. This approach leads to inaccuracies for the estimation of car traffic flows, since the parking situation is neglected. To overcome these inaccuracies and fill this research gap, we have developed a method to determine the car-access attractiveness of districts for shopping and working trips. Our method consists of two steps. First, we determine the car-access attractiveness of buildings within a district based on the parking situation of each individual building and then aggregate the results at the district level. The approach is demonstrated for the city of Berlin. The results confirm that conventional models cannot be used to determine the car-access attractiveness of districts. According to these models, attractive districts are predominantly located in the city centre due to the large amount of sales areas or the large number of employees. However, due to the high density of buildings, only limited space is available for parking. Attractive districts rated according to our new approach are mainly located in the outer areas of the city and thus match the parking situation.

show abstract

“…Knowing the need to decrease pollution (mainly air) around the globe, we must reduce the emissions caused by the transport sector by shifting away from the traditional fossil fuel-based concept to an alternative system [8][9][10]. With numerous objectives to be achieved (and quickly), electric vehicles (EVs) are set to be the key to shift into electric mobility, considering that they have already been playing a significant role in recent years [6,8].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Scenarios for the Insertion of Electric Vehicles in Conjunction with a Solar Carport in the City of Curitiba, Paraná—Brazil

et al. 2021

View full text Add to dashboard Cite

The growing environmental impact and rising emission of greenhouse gases have accelerated the research toward renewable energy sources and electric vehicles since one of the main sources of pollution is the CO2 emissions produced by conventional combustion vehicles. This article presents the analysis of the energy balance between a photovoltaic carport with 4.89 kWp installed capacity and an EV, model Renault Fluence ZE DYN, driven in real conditions. The driving tests were performed during the winter season in the city of Curitiba, the capital of the state of Paraná, Brazil, with approximately 1.7 million inhabitants and 1.1 million vehicles. During the test period, we attempt to reproduce the citizen’s daily routes through the city, presenting an average consumption of 15.75 kWh/100 km. The carport PV module’s energy generation and in-plane incident irradiation were acquired to calculate the performance ratio, making a comparison after cleaning maintenance possible. The solar carport system has 4.89 kWp and has generated an average of 465.37 kWh during its 24 months of operation. The analysis scenarios consist of replacing part of the city’s combustion vehicle fleet with the EVs (the same as used in the study) and thus determining how many replicas of the presented photovoltaic systems might be needed, as well as the area required for the installations. In a simulation with 15% of the fleet’s replacement, it would be necessary to generate 17,151.8 MWh, which requires the construction of 36,856 carports, covering an area of approximately 1,105,685 m². Finally, an economic comparison between an internal combustion vehicle and the EV determined that the expenditures involving electric energy to charge the batteries are 3.3 times lower than buying gasoline, assuming the same driving routines.

show abstract

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

Cited by 17 publications

References 24 publications

Incorporating time-dependent demand patterns in the optimal location of capacitated charging stations

Incorporating time-dependent demand patterns in the optimal location of capacitated charging stations

Car-Access Attractiveness of Urban Districts Regarding Shopping and Working Trips for Usage in E-Mobility Traffic Simulations

Analysis of Scenarios for the Insertion of Electric Vehicles in Conjunction with a Solar Carport in the City of Curitiba, Paraná—Brazil

Contact Info

Product

Resources

About