Your search keyword '"Dietmar Göhlich"' showing total 4 results

1. Analysis of Charging Infrastructure for Private, Battery-electric Passenger Cars: Optimizing Spatial Distribution using a Genetic Algorithm

Author

Diego Fadranski, Anne Magdalene Syré, Alexander Grahle, and Dietmar Göhlich

Subjects

automotive_engineering

Abstract

To enable the deployment of battery-electric vehicles (BEV) as passenger cars in the private transport sector, a suitable charging infrastructure is crucial. In this paper a methodology for efficient spatial distribution of charging infrastructure is evaluated by investigating a scenario with a market penetration of BEVs of 100 percent (around 1.3 million vehicles). It aims towards the development of various charging infrastructure scenarios - including public and private charging - which are suitable to cover the charging demand. Therefore, these scenarios are investigated in detail with focus on number of public charging points, their spatial distribution, the available charging power and the necessary capital costs. For the creation of those charging infrastructure scenarios a placement model is developed. It uses the data of a MATSim (Multi-Agent Transport Simulation) traffic simulation of the metropolitan area of Berlin to evaluate and optimize different distributions of charging infrastructure. The model uses a genetic algorithm and the principle of multi-objective optimization. The capital cost of the charging points and the mean detour car drivers must cover additionally are used as optimization criteria. Using these criteria should lead to cost efficient infrastructure solutions which provide high usability at the same time. The main advantage of the method selected is that multiple optimal solutions with different characteristics can be found and suitable solutions can be selected by using other criteria subsequently. The optimized charging infrastructure solutions show capital costs between 624 and 2950 million euro. Users must cover an additionally mean detour of 254m to 590m per charging process to reach an available charging point. According to the results a suitable ratio between charging points and vehicles is between 11:1 and 5:1. A share of fast charging infrastructure (>50kW) of less than ten percent seems to be sufficient, if it is situated at main traffic routes and highly frequented places.

Published

2022

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

Author

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

Subjects

conceptual vehicle design, Computer science, decarbonization methodology, TJ807-830, TD194-195, urban traffic, charging concepts, Renewable energy sources, Procurement, life cycle assessment, Vehicle routing problem, 380 Handel, Kommunikation, Verkehr, GE1-350, Environmental impact assessment, Life-cycle assessment, automotive_engineering, Environmental effects of industries and plants, business.industry, battery electric vehicles, Environmental economics, Total cost of ownership, sustainability, Environmental sciences, ddc:380, Technical feasibility, agent-based transport simulation, Public transport, Greenhouse gas, vehicle routing problem, business, total cost of ownership

Abstract

This paper presents a new methodology to derive and analyze strategies for a fully decarbonized urban transport system which combines conceptual vehicle design, a large-scale agent-based transport simulation, operational cost analysis, and life cycle assessment for a complete urban region. The holistic approach evaluates technical feasibility, system cost, energy demand, transportation time, and sustainability-related impacts of various decarbonization strategies. In contrast to previous work, the consequences of a transformation to fully decarbonized transport system scenarios are quantified across all traffic segments, considering procurement, operation, and disposal. The methodology can be applied to arbitrary regions and transport systems. Here, the metropolitan region of Berlin is chosen as a demonstration case. The first results are shown for a complete conversion of all traffic segments from conventional propulsion technology to battery electric vehicles. The transition of private individual traffic is analyzed regarding technical feasibility, energy demand and environmental impact. Commercial goods, municipal traffic and public transport are analyzed with respect to system cost and environmental impacts. We can show a feasible transition path for all cases with substantially lower greenhouse gas emissions. Based on current technologies and today&rsquo, s cost structures our simulation shows a moderate increase in total systems cost of 13&ndash, 18%.

Published

2020

3. Environmental Impact of Subsidy Concepts to Stimulate Car Sales in Germany

Author

Ludger Heide, Alexander Grahle, Anne Magdalene Syré, Malte Scharf, and Dietmar Göhlich

Subjects

Coronavirus disease 2019 (COVID-19), business.industry, Automotive industry, Subsidy, Environmental impact assessment, business, Industrial organization, automotive_engineering

Abstract

This paper establishes a prognosis of the long term environmental impact of various car subsidy concepts. The CO2 emissions of the German car fleet impacted by the purchase subsidies are determined. A balance model of the CO2 emissions of the whole car life cycle is developed. Consideration of production-, use- and End-of-Life processes are taken into account. The implementation of different subsidy scenarios directly affects the forecasted composition of the vehicle population and therefore the resulting life cycle assessment. All scenarios compensate the additional emissions required by the production pull-in within the considered period and hence reduce the accumulated CO2 emissions until 2030. The exclusive funding of BEVs is most effective with a break-even in 2025.

Published

2020

4. A Comprehensive TCO Evaluation Method for Electric Bus Systems Based on Discrete-Event Simulation Including Bus Scheduling and Charging Infrastructure Optimisation

Author

Dietmar Göhlich and Dominic Jefferies

Subjects

Operations research, Computer science, optimisation, charging infrastructure, Scheduling (computing), depot charging, Bus network, Procurement, Electrification, opportunity charging, electric bus, Genetic algorithm, genetic algorithm, scheduling, Discrete event simulation, lcsh:TA1001-1280, Total cost of ownership, simulation, engineering_other, TCO, Local bus, lcsh:Electrical engineering. Electronics. Nuclear engineering, ddc:620, lcsh:Transportation engineering, bus network, lcsh:TK1-9971

Abstract

Bus operators around the world are facing the transformation of their fleets from fossil-fuelled to electric buses. Two technologies prevail: Depot charging and opportunity charging at terminal stops. Total cost of ownership (TCO) is an important metric for the decision between the two technologies, however, most TCO studies for electric bus systems rely on generalised route data and simplifying assumptions that may not reflect local conditions. In particular, the need to reschedule vehicle operations to satisfy electric buses&rsquo, range and charging time constraints is commonly disregarded. We present a simulation tool based on discrete-event simulation to determine the vehicle, charging infrastructure, energy and staff demand required to electrify real-world bus networks. These results are then passed to a TCO model. A greedy scheduling algorithm is developed to plan vehicle schedules suitable for electric buses. Scheduling and simulation are coupled with a genetic algorithm to determine cost-optimised charging locations for opportunity charging. A case study is carried out in which we analyse the electrification of a metropolitan bus network consisting of 39 lines with 4748 passenger trips per day. The results generally favour opportunity charging over depot charging in terms of TCO, however, under some circumstances, the technologies are on par. This emphasises the need for a detailed analysis of the local bus network in order to make an informed procurement decision.

Published

2020