MAHLE 17th Stuttgart Entwicklungen International für Symposium den Antrieb von heute und morgen MAHLE Products and Systems Driving Today's and Tomorrow's Powertrain 1 17th Stuttgart International Symposium 14-15 March 2017 Wolf-Henning Scheider CEO of the MAHLE Group
Trends and Challenges in a Changing Mobility World DIGITAL TECHNOLOGY New Mobility Concepts Connected Car Local Pollutants Autonomous Driving Green House Gases Multiple / CO 2 factors influencing modern vehicle development EMISSIONS 2
The Solution? Zero Emission? Electric vehicles with zero local emissions 3
What is the CO 2 footprint of electric energy? It depends on the energy mix and the time of charging! 100% Renewables 90% 28 % 43 80% Nuclear % 70% vs. Gas Oil 60% 50% 40% 30% Day Night Solids 20% 10% 0 2015 2020 2025 2030 vs. EU power generation by fuel [Source: Publication European Commission 2016] Wind Calm CO 2 footprint of electric energy depends on several factors 4
MAHLE Future Worlds (Base and Extreme Scenarios) Powertrain mix Well-to-wheel Green zones Green planet Statutory regulations 1 Base Scenario CHIndia Asian growth Localization Price aggressive suppliers 2 Autonomous driving Car sharing Connected cars LV volume reduction Mr. Roboto 2030 4 3 Automotive mega suppliers Margin pressure Built to print Increased Tier 2 business New Order High degree of uncertainty leads to various future scenarios 5
Dual Strategy HVAC Highly efficient combustion engines Emerging markets New projects Thermal management Commercial vehicles & Off-Highway Aftermarket Electric drives Electric auxiliaries Dual Strategy to consequently further develop ICEs and electric drives at the same time 6
MAHLE 1.2l DI3 CNG 17th Stuttgart International Symposium Natural Gas and Methane Specific Engine Components CO 2 reduction potential of Natural gas (WLTC*) Synthetic Methane (WtW**) >25% >95% MAHLE competence to design specific engine components for gas applications 7 *) WLTC: Worldwide Harmonized Light-Duty Vehicles Test Cycle **) WtW: Well-to-Wheel
MAHLE Jet Ignition Lean Burn Combustion Process Very low raw pollutants Thermal efficiency η th up to 45% Innovative lean burn process to increase efficiency of gasoline engines 8
Driving range [%] Driving range in % @0 C 17th Stuttgart International Symposium Heat Pump Heating System for Electric Vehicles 120% only -17% only -8% Compared to HV-PTC* technology: High efficiency High driving range in winter 100% 80% 60% 40% 100% 100% 83% 60% 79% 92% w/o HV-P Heat 20% 0% compact vehicle medium size vehicle w/o heating HV-PTC* (COP**=1) Heat Pump (COP**=3.2) MAHLE heat pump systems increase heating efficiency significantly 9 *) HV-PTC: High Voltage Positive Temperature Coefficient Ceramic Heating **) COP: Coefficient of Performance
CO 2 Refrigerant R744 HVAC System Natural refrigerant Incombustible Faster* cabin cool-down possible Gas cooler p, T-Sensor FXV-BY Evaporator Compressor Accumulator-IHX Combi-Unit Environmental friendly refrigerant for modern HVAC systems 10 *) Compared to R1234yf
Kapazität Capacity [%] [%] Kapazität Capacity [%] 17th Stuttgart International Symposium Battery Thermal Management for Electric Vehicles Optimal battery temperature Remaining high capacity over lifetime Fast charging capability Cell degradation (Lithium Ion) 100 100 Battery aging (Lithium Ion) 80 T = 10 C 80 60 40 T = 0 C T = -20 C 60 40 T = 25 C T = 55 C 20 20 0 0 20 40 60 80 100 Cycles Zyklen 0 0 200 400 600 800 1000 Zyklen Cycles Next generation of batteries require even more powerful thermal management systems 11
Conclusions More powertrain variants with unpredictable volume shares require high flexibility for suppliers Increase agility and resilience Emission targets only achievable with innovations in combustion engines and fuels Technology-open discussion required Focus on energy efficiency and climate protection of secondary systems like HVACs Strong business case for innovations Potential for low voltage traction motors for urban vehicle applications Prepare for additional vehicle types 12