Well-to-Wheel Analysis of Electrified Drivetrains under Realistic Boundary Conditions and User Behaviour

Similar documents
Holistic Energy Analysis of Various Drivetrain Topologies Close to Reality

Optimierungsstrategien für den Brennstoffzellenantrieb

Progress on FCEV development and conditions for FCEV market introduction

Daimler's perspective on alternative propulsion systems and the new Mercedes GLC F-CELL. Dr. rer. nat. Jörg Wind Daimler Group, Kirchheim/Teck-Nabern

Dr. Jörg Wind Daimler s road to FCEV market introduction

FUTURE TRANSPORT SYSTEMS: E-MOBILITY, HYDROGEN AND FUEL CELLS

HYSYS System Components for Hybridized Fuel Cell Vehicles

HySYS: Fuel Cell Hybrid Vehicle System Component Development

Co-Simulation of GT-Suite and CarMaker for Real Traffic and Race Track Simulations

Future Energy Systems and Lifestyle

The role of Hydrogen in Sustainable Mobility

ECODESIGN BATTERIES FIRST STAKEHOLDER MEETING DRAFT TASK 3

Electric Mobility at Opel Strategy. Technology. The Ampera. Gerrit Riemer Adam Opel AG Director Future Mobility Mobilis 2012, Mulhouse

EVs and PHEVs environmental and technological evaluation in actual use

IA-HEV Task 15. Plug-in Hybrid Electric Vehicles. Phase 1 Findings & Phase 2 Recommendations

2010 Advanced Energy Conference. Electrification Technology and the Future of the Automobile. Mark Mathias

A pathway for the evolution of the refining industry and liquid fuels in Europe

Research on Automotive Propulsion Systems for Future Mobility Needs

Influences of different heating concepts for the energy demand of an airfield luggage tug

Holistic 1D-Model for Cooling Management and Engine Analysis of a Heavy-Duty Truck

Infraday: The Future of E-Mobility

INNOVATION FROM THE PERSPECTIVE OF AN AUTOMOTIVE SUPPLIER

The electrification of the automobile Fuel Cell Electric Vehicles and Battery Electric Vehicles Dr. Jörg Wind

Road to sustainable mobility

THE FUTURE OF ROAD VEHICLES

Alternative Powertrain and Challenges for Next Decade

Electrified Buses in Brussels: Design Considerations and Charging Strategy. Omar Hegazy & Thierry Coosemans VUB-MOBI

Fuel Cell Hybrid Vehicle System Component Development

MAGNA DRIVETRAIN FORUM 2018

Buses ensure environmentally friendly mobility Wolfgang Fahrnberger - Chairman of the Management at NEOMAN Bus GmbH

Systems Analysis of China s Fuel/Vehicle Alternatives: Policy Implications for 2020

A portfolio of power-trains for Europe: a fact-based analysis

OPTIMAL POWER MANAGEMENT OF HYDROGEN FUEL CELL VEHICLES

Seoul, Korea. 6 June 2018

The Electrification of the Vehicle and the Urban Transport System

Scenarios and Technologies for Decarbonization of Road Transport 2050 Peter Prenninger - AVL List GmbH

Energy Demand & World Oil Production : Forecast. World Oil Production by Source

EE Architecture for Highly Electrified Powertrain

12V / 48V Hybrid Vehicle Technology Steven Kowalec

System Engineering for Energy Storage Systems

Current Progress of DaimlerChrysler's Fuel Cell Powered Fleets. Dr. Klaus Bonhoff

D6.5 Public report on experience & results from FCEV city car demonstration in Oslo

Transitioning to low carbon / low fossil fuels and energy sources for road transport

Holistic Method of Thermal Management Development Illustrated by the Example of the Traction Battery for an Electric Vehicle

Integrated Powertrain Simulation for Energy Management of Hybrid Electric Vehicles

EU Projekt HySYS Fuel Cell Hybrid Vehicle System Component Development

Honda Clarity Fuel Cell HyLAW National Workshop, Budapest, 27. September 2018

ACstyria Hotspot FCH. Building Synergies for Mobility The European Perspective. Graz, October 22 and 23, 2015

Siemens Pioneer in Electric Mobility

State of the art cooling system development for automotive applications

Einstecken können wo, wie und wieviel? Ladeinfrastruktur für Elektrofahrzeuge

Mercedes-Benz Citaro Fully Electric City Bus. Gustav Tuschen Head of Product Engineering Daimler Buses

Evaluation of exhaust emissions from three dieselhybrid. cars and simulation of after-treatment

HyPM HD Fuel Cell Systems for Heavy Duty Green Mining. OnSite Generation Water Electrolyzers. Energy Storage Power Systems Power Modules

Eco-Mobility 2025 plus Vienna, On the road to a sustainable mobility

Hybrids & Electromobility New prerequisites and customer values

Recent Developments in Electric Vehicles for Passenger Car Transport

AUTOMOTIVE ELECTRIFICATION

Procedure to assess the consumption and the thermal comfort of a passenger car MAC system

LINAMAR Success in a Rapidly Changing Automotive Industry

Progress Report. Low and Realistic Winter Temperature TF WLTP 21 th - January The European Commission s science and knowledge service

COMPETITIVE COST ANALYSIS OF ALTERNATIVE POWERTRAIN TECHNOLOGIES

Transmission Technology contribution to CO 2 roadmap a benchmark

Looking into the Future

HERGOTT Julien & MOISY Alexandre EHRS modelling with GT-Suite European GT Conference 2015

EVREST: Electric Vehicle with Range Extender as a Sustainable Technology.

Optimal Control Strategy Design for Extending. Electric Vehicles (PHEVs)

The Future of Powertrain The Voltage is Rising!

ELECTRICAL 48 V MAIN COOLANT PUMP TO REDUCE CO 2 EMISSIONS

MODULAR WATER CHARGE AIR COOLING FOR COMBUSTION ENGINES

Umicore and clean mobility

Vehicle Electrification: You'll Get a Charge Out of This!

E-MOBILITY TESTING ALONG THE V-CYCLE EMPHASIS ON THE INTEGRATION TESTBENCH. Markus Maier, RBM Germany

AN LCA COMPARISON OF POWERTRAINS AND FUELS TODAY AND 2030

THERMAL MANAGEMENT SYNERGY THROUGH INTEGRATION PETE BRAZAS

Market integration of electric mobility: Analyzing economic efficiency and costs for consumers

Experience with emissions from a PHEV and RDE data evaluation methods

Curbing emissions and energy consumption in the transport sector how can we deal with it in Warsaw 2012 Annual POLIS Conference

Well-to-Wheels analysis of future automotive fuels and powertrains in the European context

Multi-disciplinary Design of Alternative Drivetrains an Integrated Approach for Simulation and Validation

Clean vehicles & fuels in the EU

H 2 : Our path to a sustainable society

Integration of electric vehicles (EV) into the future energy supply system

Young Researchers Seminar 2015

Testing of Emissions- Relevant Driving Cycles on an Engine Testbed

WCTRS International Conference: Transport, Climate Change and Clean Air, Paris, June 21, 2018

Our Commitment to Commercialization of Fuel Cell Vehicles and Hydrogen Infrastructure

Electric vehicles a one-size-fits-all solution for emission reduction from transportation?

MECA0500: PLUG-IN HYBRID ELECTRIC VEHICLES. DESIGN AND CONTROL. Pierre Duysinx

NEW-GENERATION ELECTRIC VEHICLES

4th ACEM Annual Conference

2011 Advanced Energy Conference -Buffalo, NY

and Electric Vehicles ECEN 2060

EU-Commission JRC Contribution to EVE

B-COOL. Low Cost and High Efficiency CO 2 Mobile Air Conditioning system for lower segment cars

Electrical 48-V Main Coolant Pump to Reduce CO 2 Emissions

ehighway Electrified heavy duty road transport Unrestricted Siemens AG 2018

All-in-one Simulation and DoE Methodology for the Evaluation and Optimisation of HEV Configurations. W.-R. Landschoof, M. Kämpfner, Dr. M.

NEW ENERGY -4- MOBILITY TECHNOLOGIES

THE FUTURE DIRECTION OF THE ELECTRIFIED VEHICLE UTILIZING OF BIG DATA

Transcription:

Well-to-Wheel Analysis of Electrified Drivetrains under Realistic Boundary Conditions and User Behaviour Benedikt Hollweck European GT Conference, Frankfurt am Main, 17 th October 2016

Agenda 1. What is a well-to-wheel analysis and why do we need realistic boundary conditions and user behaviour? 2. Methodology for the approach to represent realistic boundary conditions and user behaviour for a well-to-wheel analysis 3. Drivetrains modelled with GT-SUITE Fuel Cell Electric Vehicle (FCEV) Fuel Cell Plug-In Electric Vehicle (FC PHEV) Battery Electric Vehicle (BEV) 4. Possibility to analyse the fuel consumption for different users 5. Well-to-wheel analysis for the typical German driver behaviour 6. Summary Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 2

Well-to-Wheel Analysis A well-to-wheel analysis is the rating of energy consumption and greenhouse gas emissions arising on the path from the energy source to the wheel. Well-to-Wheel Analysis (WtW) Well-to-Tank (WtT) Tank-to-Wheel (TtW) Fuel production Vehicle operation Evaluation criteria: Energy consumption Greenhouse gas emissions Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 3

GHG* Emissions [g CO 2 eq/km] WtW-Analysis: CO 2 - and Energy comparison of EUCAR reference vehicles 2020+ Fuel Cell: Battery: High range (> 500 km), short refueling time (3 min), applicable for different vehicle concepts Optimal operation in compact cars for the city traffic (200-250 km), recharging over night 150 125 100 75 50 25 PH-FCEV (Wind-Electricity, Grid, Centr. Electrolysis, CH2, PlugIn Hybrid-FCEV) BEV (Wind-/PV-/Water-Electricity, Grid, Battery EV Li-Ion) 0 20 40 60 80 100 120 140 160 180 200 *GHG: Green House Gas FCEV (NG 4000km, Centr. ref., Road, CH2, FCEV) Fuel Cell-EV Hybrid ICE Hybrid Gasoline Hybrid Diesel Battery-EV BEV (EU-Electricity-Mix, Grid, Battery EV Li-Ion) FCEV (Wind-Electricity, Grid, Centr. Electrolysis, CH2, FCEV) ICE = Internal combustion engine BEV = Battery electric vehicle FCV = Fuel cell vehicle PHFCV = Plug-In hybrid fuel cell vehicle Source: JEC, Well-to-Wheel report (version 4), 2014 Electric drivetrains are a real step to reduce energy consumption and GHG-emissions. Using EVs means a significant step forward. Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 4 Diesel Energy Consumption Well-to-Wheel [MJ/100km] ICE Gasoline CNG

0-1 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-9 9-10 10-11 11-12 12-13 13-14 14-15 15-16 16-17 17-18 18-19 19-20 20-21 21-22 22-23 23-24 Frequency in % Frequency Methodology for the approach to represent realistic boundary conditions and user behaviour for a WtW-analysis Driving performance (MiD) 3 Artemis driving cycles User behaviour (Track-type, traffic flow, typical driver) GT-SUITE vehicle simulation model Driving distance Data of the study: Mobilität in Deutschland (MiD 2008) Small Reference vehicles Medium Large Reference vehicles (small, medium, large) Evaluation by track type and track length 10 9 8 7 6 5 4 3 2 1 0 Cluster 1 0 9 am 23,59% Average value: 7:06 1 hour simulation duration Starting times (MiD) Cluster 2 9 am 1 pm 23,39% 10:54 Cluster 3 1 4 pm 19,82% 14:36 Starting time in h Cluster 4 4 7 pm 23,16% 17:18 Cluster 5 7 12 pm 10,05% 20:36 4*5 climate clusters for Germany Climate boundary conditions and start conditions Specific daytime, track type and track length Results: Realistic energy consumption of a specific user Weighting factors of the study Mobilität in Deutschland Results: Realistic energy consumption for a typical German driver Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 5

Methodology Modular vehicle simulation with GT-SUITE Drivetrain: BEV FC-PHEV / FC-RE FCEV PHEV / RE HEV ICE gasoline ICE diesel ICE CNG Submodel 2 Submodel 1 Auxiliary consumer Operation Fuel cell system strategy Input driving performance Reg. braking Battery Electric motor Single stage transmission Reference vehicle Vehicle architecture: Reference vehicle small Reference vehicle medium Reference vehicle large + Driving cycle NEDC Driving cycle WLTP 3 x Driving cycles user behaviour Submodel 3 Vehicle cabin Submodel 4 Thermal management: Drivetrain BEV Drivetrain ATS FCPHEV Drivetrain ATS FCEV Drivetrain ATS PHEV Drivetrain ATS HEV Drivetrain ATS ICE gasoline Drivetrain ATS ICE diesel Drivetrain ATS ICE CNG Data bus Analysis Radiator control HT cooler FC stack thermal Heat exchanger Intercooler Pipe losses Fresh air supply Fan control Vehicle cabin: Vehicle cabin small Vehicle cabin medium Vehicle cabin large PTC Evaporator control Bypass control Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 6

Simulation model Fuel Cell Plug-In Electric Vehicle (FCPHEV) Operation strategy Auxiliary consumer Input driving performance Fuel cell system Reg. braking Data bus Analysis Electric motor Single stage Transmission Reference vehicle Chiller Vehicle cabin Low temperature circuits Battery Radiator control HT cooler Intercooler FC stack thermal Fresh air supply Heat exchanger Fan control PTC Evaporator control Bypass control Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 8

Simulation model Battery Electric Vehicle (BEV) Auxiliary consumer Reg. braking Input driving performance Reference vehicle Electric motor Single stage Transmission Data bus Analysis Battery Vehicle cabin Radiator control LT circuit Fresh air supply Fan control Heat exchanger PTC Bypass control Evaporator control Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 9

Validation of the simulation models NEDC fuel consumption Fuel consumption Fuel Cell Electric Vehicle: Characteristic Certified fuel consumption Mercedes-Benz B-Class F-CELL Simulated fuel consumption Mercedes-Benz B-Class F-CELL H 2 consumption [kgh 2 /100km] 0,97 0,965 Fuel consumption Battery Electric Vehicle: Characteristic Certified fuel consumption Mercedes-Benz B-Class electric drive Simulated fuel consumption Mercedes-Benz B-Class electric drive Energy consumption [kwh/100km] 16,6 16,61 Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 10

Energy consumption in kwh/100km Validation of the simulation model Fuel consumption at different temperatures 50 Energy consumption at different temperatures simulated and measured 45 Data from the ÖVK-study Simulation 40 35 30 25 20 15-20 -10 0 10 20 30 Ambient temperature in C Source: Batterieelektrische Fahrzeuge in der Praxis, Österreichischen Vereins für Kraftfahrzeugtechnik (ÖVK), 2016 Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 11

0-1 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-9 9-10 10-11 11-12 12-13 13-14 14-15 15-16 16-17 17-18 18-19 19-20 20-21 21-22 22-23 23-24 Frequency in % Frequency Methodology for the approach to represent realistic boundary conditions and user behaviour for a WtW-analysis Driving performance (MiD) 3 Artemis driving cycles User behaviour (Track-type, traffic flow, typical driver) GT-SUITE vehicle simulation model Driving distance Data of the study: Mobilität in Deutschland (MiD 2008) Small Reference vehicles Medium Large Reference vehicles (small, medium, large) Evaluation by track type and track length 10 9 8 7 6 Cluster 1 0 9 am 23,59% Average value: 7:06 1 hour simulation duration Starting times (MiD) Cluster 2 9 am 1 pm 23,39% 10:54 Cluster 3 1 4 pm 19,82% 14:36 Cluster 4 4 7 pm 23,16% 17:18 Cluster 5 7 12 pm 10,05% 20:36 4*5 climate clusters for Germany Climate boundary conditions and start conditions Specific daytime, track type and track length 5 4 3 2 1 0 Starting time in h Results: Realistic consumption of a specific user Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 12

Energy consumption in kgh 2 / 100km Fuel consumption of specific users driving a Fuel Cell Electric Vehicle Urban driver Drive Drive 1 Drive 2 Drive 3 Starting time 7:06 CET 17:18 CET 20:36 CET Drives per week 5 5 2 Driving distance 3 6 km 3 6 km 1 3 km Road type Urban Urban Urban 1,5 1,25 1 Average fuel consumption in kgh 2 /100 km Rural driver Drive Drive 1 Drive 2 Drive 3 Starting time 7:06 CET 17:18 CET 20:36 CET Drives per week 5 5 2 Driving distance 15 30 km 15-30 km 15 30 km Road type Rural Rural Rural 0,75 0,5 0,25 0 Average of German users Rural driver Urban driver Average of German users Rural driver Urban driver With this methodology an analysis of different user types is possible. Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 13

0-1 1-2 2-3 3-4 4-5 5-6 6-7 7-8 8-9 9-10 10-11 11-12 12-13 13-14 14-15 15-16 16-17 17-18 18-19 19-20 20-21 21-22 22-23 23-24 Frequency in % Frequency Methodology for the approach to represent realistic boundary conditions and user behaviour for a WtW-analysis Driving performance (MiD) 3 Artemis driving cycles User behaviour (Track-type, traffic flow, typical driver) GT-SUITE vehicle simulation model Driving distance Data of the study: Mobilität in Deutschland (MiD 2008) Small Reference vehicles Medium Large Reference vehicles (small, medium, large) Evaluation by track type and track length 10 9 8 7 6 Cluster 1 0 9 am 23,59% Average value: 7:06 1 hour simulation duration Starting times (MiD) Cluster 2 9 am 1 pm 23,39% 10:54 Cluster 3 1 4 pm 19,82% 14:36 Cluster 4 4 7 pm 23,16% 17:18 Cluster 5 7 12 pm 10,05% 20:36 4*5 climate clusters for Germany Climate boundary conditions and start conditions Specific daytime, track type and track length Weighting factors of the study Mobilität in Deutschland 5 4 3 2 1 0 Starting time in h Results: Realistic energy consumption of a specific user Results: Realistic energy consumption for a typical German driver Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 14

Summary The approach of a Well-to-Wheel analysis was introduced and the need to compare different drivetrain topologies under realistic boundary conditions and user behaviour was explained. A methodology to represent realistic boundary conditions and user behaviour for a Well-to-Wheel Analysis was presented. The simulation models of a Fuel Cell Electric Vehicle, a Fuel Cell Plug-In Electric Vehicle and a Battery Electric Vehicle were shown and explained. The possibility to get realistic energy consumptions for different user types, the German driving performance and different vehicle sizes were pointed out. Daimler AG GT-Conference / Benedikt Hollweck / 17.10.2016 / Page 16

Thank you for your attention!

2024 © autodocbox.com Privacy Policy | Terms of Service | Feedback