Analysis of different sector coupling paths for CO 2 mitigation in the German Transport sector Click to edit Master subtitle style Felix Kattelmann Markus Blesl Source: Forschungszentrum Jülich/Tricklabor for the Kopernikus project Power-to-X Felix Kattelmann, Markus Blesl
Outline 1. Introduction 2. TIMES Model General modelling approach Implementation of trolley trucks E-Mobility Scenario Analyses 3. Results 4. Conclusion 2
Motivation German national targets for reducing the Greenhouse Gas emissions compared to 1990 [1] 2015 2020 2030 2040 2050 overall GHG emissions -27.2% -40% -55% -70% -80% to -95% ambitious goals for GHG emission reductions almost complete decarbonisation of the entire German energy system necessary need of renewables in heat and transport sector potentials of renewables mostly in electricity sector sector coupling 3
TIMES-D model Felix Kattelmann, Markus Blesl
TIMES-D model General modelling approach depiction of the entire German energy system derived from the TIMES-PanEU model linear optimization: total system costs minimized complete competition between different technologies assumed GHG emissions of the system are recorded division into 280 time segments of 3 hours each model horizon: 2010-2050 determination of the economically optimal energy supply structure for a given target 5
TIMES-D model Implementation of Trolley Trucks technology characteristics electrically powered trucks energy supply via pantograph and overhead lines construction of the necessary infrastructure over motorways (as discussed) cost-intensive modelling picture: dpa/picture-alliance one of multiple technologies in transport sector selection of technologies in model dependent on process-costs (amongst other things) e.g. investment or maintenance costs contribution to meeting the freight traffic demand limited to 90% 6
TIMES-D model Implementation of Trolley Trucks more accurate modelling of infrastructure costs for complete electrification of motorways distributed over assumed max. number of vehicles problem: clear differences in the utilisation of motorways in Germany overhead lines over heavily used motorways can power more vehicles than over low-frequented ones new implementation infrastructure costs distributed unevenly over three stages stage 1: 1/3 of vehicles but 1/6 of infrastructure potential of one stage limited to 1/3 of the max. overall contribution from Trolley Trucks investment cost Trolley Trucks previous implementation infrastructure vehicle new implementation 3/6 2/6 1/6 stage 1 stage 2 stage 3 7
TIMES-D model Modelling of e-mobility electricity grid mobility demand electric vehicle charging infrastructure battery Power-to-grid electricity grid e-mobility: all electrically operated vehicles in transport sector (except for heavy goods traffic and trains) sufficient charging infrastructure has to be used to charge the batteries Power-to-grid possible one of multiple technology pathways in transport sector 8
TIMES-D model scenario analyses gradual reduction of the system s GHG emissions three scenarios with great differences in the longterm reduction targets Trolley Trucks: scenario S90 with and without disaggregated infrastructure analysis of the charging infrastructure s influence share of simultaneously usable infrastructure limited to 10%, 50% and 90% Reduction of overall GHG emissions scenario 2020 2030 2050 S80-40% -55% -80% S90-40% -55% -90% S95-40% -58% -95% 9
Results Felix Kattelmann, Markus Blesl
Freight demand in tkm Results Freight Traffic potential of the Trolley Truck 600,000 500,000 400,000 300,000 200,000 100,000 0 Meeting the demand of freight transport S80 S90 S95 S80 S90 S95 S80 S90 S95 S80 S90 S95 2035 2040 2045 2050 Years Trolley Truck Rest huge discrepancy between the scenarios: entire possible demand provided by Trolley Trucks in S95 no usage at all in S80 deployment of trolley trucks highly dependent on the selection of GHG reduction targets 11
base S90 base S90 base S90 base S90 base S90 Final enegry consumption in PJ Results Freight Traffic influence of disaggregated infrastructure modelling 1000 900 800 700 600 500 400 300 200 100 0 Final energy consumption in heavy road freight traffic Hydrogen Electricity Natural Gas Diesel Biofuels share of electricity: 30% (disaggregated infrastructure) 21% (base) usage of Trolley Trucks depends strongly on the modelling of infrastructure 2030 2035 2040 2045 2050 Years 12
Electrical load in GW Results Freight Traffic Overall electrical load from trolley trucks in 2050 20 18 Monday Tuesday Wednesday Thursday Friday Saturday 16 14 12 10 8 6 4 2 S80 S90 S95 13.3 GW additional load in S90 18 GW additional load in S95 load directly dependent on driving behaviour 0 day of the week 13
Demand of personal transport in pkm Results E-Mobility Meeting the personal transport demand 1,000,000 900,000 800,000 no difference between the scenarios until 2035 700,000 600,000 500,000 400,000 Rest contribution of electric vehicles varies between 21% (scenario S80) and 75% (S95) in 2050 300,000 200,000 100,000 0 S80 S90 S95 S80 S90 S95 S80 S90 S95 S80 S90 S95 S80 S90 S95 S80 S90 S95 Electric Vehicles choice of the long-term target has a major impact on the utilization of electric vehicles 2025 2030 2035 2040 2045 2050 Years 14
Electrictiy consumption in PJ Results E-Mobility 2500 Electricity Consumption by sector 2000 1500 1000 500 0 S80 S90 S95 S80 S90 S95 S80 S90 S95 2030 2040 2050 Years E-Mobility Remaining Transport Supply Residential Industry Comercial Agriculture higher electricity consumption in 2050 due to electrification of all sectors in the S95 scenario e-mobility accounts for 10% of the total power consumption in 2050 (280 PJ) S95: 190 PJ more by e-mobility compared to S80 15
Results E-Mobility electrical load caused by charging huge peaks for 50% availability 16
Results E-Mobility residual load and load by charging 17
Conclusion Felix Kattelmann, Markus Blesl
Conclusion contribution of the Trolley Truck heavily dependent on the choice of emission reduction targets with no usage at all in the S80 scenario maximal electrical load of trolley trucks is 18 GW, likely to vary significantly between different regions significant influence of detailed modelling of infrastructures on the results of Trolley Truck analyses GHG emission reduction targets with major impact on the utilisation of e-mobility (varying between 21% and 75%) the load caused by charging electric vehicles can be regulated by limiting the simultaneousness of the charging infrastructure by not limiting the simultaneousness e-mobility can serve as a very useful flexibility option, causing large additional loads of around 40 GW however 19
References [1] BMWi, Die Energie der Zukunft - Vierter Monitoring-Bericht zur Energiewende, Bundesministerium für Wirtschaft und Energie (BMWi), Tech. Rep., 2015. [2] Bundesministerium für Wirtschaft und Energie, Energieffizienz in Zahlen, Tech. Rep., 2017. [3] M. Wietschel et al., Machbarkeitsstudie zur Ermittlung der Potentiale des Hybrid-Oberleitungs-Lkw, Fraunhofer ISI, Tech. Rep., 2017. [4] B. Lenz, Shell Lkw-Studie - Fakten, Trends und Perspektiven im Straßengüterverkehr bis 2030, Deutsches Zentrum für Luft- und Raumfahrt, Tech. Rep., 2010. 20
IER Institute for Energy Economics and Rational Energy Use Thank you! Felix Kattelmann e-mail felix.kattelmann@ier.uni-stuttgart.de phone +49 (0) 711 685-87845 fax +49 (0) 711 685-87873 Universität Stuttgart Institute for Energy Economics and Rational Energy Use Heßbrühlstr. 49a 70565 Stuttgart Germany This work is part of the ENavi project, financed by the Federal Ministry of Education and Research of Germany. Felix Kattelmann, Markus Blesl