RENEWABLE OPTIONS OF FUTURE MOBILITY: BEYOND OIL Dr. Sanjay Kaul Professor Fitchburg State University Fitchburg, MA
Conventional Oil reserves are concentrated in OPEC areas (>70%). The production maximum is expected within the next two decades Transportation contributes to energy consumption and greenhouse emissions Sustainable mobility requires reduction in both areas A Significant share of energy consumption is due to rising transportation activities. Today, the mobility sector is completely dependent on crude oil derivates
World Natural Resources World Oil Production P ~ 21 BBl/year Reserves R~ 649 BBl Ratio(R/P) = 649/21 ~ 31 year World natural gas Production P ~ 48TCF/Year Reserves R~ 2,470 TCF Ratio(R/P) = 2,470/48 ~ 52 years World Coal Production P~2.45 Bmt/year Reserves R~663 Bmt Ratio(R/P) = 663/2.45 ~ 270 years
World Energy Consumption 1970-2020
World Energy Consumption by Region (1970-2020)
Per Capita Energy Consumption and Share of World Population (1998/1999 data) Per-Capita Energy Consumption and Share of World Population 350 331 Per Capita Energy Consumption (in GJ) 300 Share of World Population (in %) GJ and % 250 200 174 140 150 135 100 36 50 5 0 U.S. 1 Germany 9 Europe 5 Former Soviet Union 18 Asia (w/o Japan, China) 13 12 Africa
Long term trends Continuous growth of population and energy needs Ongoing demand for mobility resulting in increasing number of cars World Population in billions North America OECD (Europe) Eastern Europe OECD (Pacific) Fast developing countries Other countries Industrialized nations Primary Energy Consumption in billion tons coal equivalent New renewable Nuclear energy Natural gas Crude oil Coal Hydro electric Wood etc. Worldwide automobile status Passenger and commercial vehicles Passenge r vehicles Commercia l vehicles
The Challenges Facing Us 4.5 4 3.5 3 2.5 2 1.5 1 0.5 Growing Petroleum Consumption 0 Urban Pollution Global Climate Change
Environmental aspects [108t ] 4.0 5.5 4.4 6.1 6.7 4.7 Other countries Fast developing countries OECD (Pacific) Eastern Europe OECD (Europe) North Amerika 1990 1995 2000 2010 2020 2030 World wide CO2-Emissions by traffic Global climatic changes are expected by steadily increasing CO2. CO2-Emissions will be limited or fined by future legislation. Toxic emissions (NOx, Hydrocarbons, Particulates etc.) from vehicles will be further restricted.
Projected Growth in Vehicle Population Intensifies Challenges Projected Growth in Light-Duty Vehicle Registrations 4 3.5 Billions of Vehicles Currently, U.S. Transportation uses 5,800 gallons of Petroleum a second 2050 3 2.5 2 1.5 1 0.5 0 2050 1996 Industrialized Nations 1996 World Source: Program Analysis Methodology: Office of Transportation Technologies, Quality Metrics 2000, Office of Transportation Technologies
Sustainable Development Approach Required Sustainable development is broadly defined as economic growth that will benefit present and future generations without detrimentally affecting the resources or biological systems of the planet.* Government and Industry share responsibility. We must approach the transportation challenge from a sustainable development perspective. *Page 149, Linking Science and Technology to Society s Environmental Goals, Policy Division National Research Council, National Academy Press, Washington D.C.
Fuels from renewable energies help to achieve the climate goal in the long run Shell predicated according to scenario analyses,that after 2050, there will be 50% renewable resources in our portfolio With today s technology, we are able to produce various fuels from renewable resources such as hydropower, wind, solar energy or biomass. Methanol (as well as ethanol, dependent on the local biomass situation ) and hydrogen are exceptionally well suited for production from co2 neutral or co2 free sources and may be used in internal combustion engines as well as fuel cell vehicles
Global Biomass Use & Resources Global Biomass Use and Resources (in TWh/a) 7000 6000 Resources Use TW h/a 5000 4000 3000 2000 1000 0 Africa Asia Europe Former Soviet Union North America South America
Renewable and Fossil Methanol Production Renewable Methanol World Biomass Wastes Methanol Natural Gas Coal Fossil Methanol World
The previous picture explains that the fuel methanol can be produced from fossil fuels such as Coal and natural gas, thus increasing co2 concentration in the atmosphere. Methanol can also be produced from co2 free or co2 neutral sources such as wood and other biomass sources, fast growing energy crops otherwise be deposited on waste disposal sites. Using these resources as an intermediary step for fuel production reduces the consumption of primary fossil fuel
Renewable and Fossil Hydrogen Production Renewable Hydrogen World Hydro Solar Power Wind Hydrogen Natural Gas Nuclear Coal Fossil Hydrogen World
The slide seen explains that the same logic holds true for a hydrogen based fuel system. In the public and political debate, it is often neglected that hydrogen is not a energy source itself but merely and energy carrier with zero carbon content. For the atmosphere it is irrelevant whether carbon dioxide is produced at the combustion location of the car or at the fuel production site. Hydrogen produced through electrolysis using renewable electricity is an option of greenhouse gas free production
Electrochemical Processes in the Proton Exchange Membrane (PEM) Fuel Cell O2 from Air e- - e Electron Flow: Usable Electricity Cathode (+) Reaction 1/2O2 + 2H+ + 2e- H2O PEM H+ (Electrolyte) H+ Anode (-) Reaction H2 2H+ + 2e+ Exhaust: Usable Heat and Clean Water H2 from Hydrogen Fuel Type
DOE s Transportation Technologies Program: Driven by a Simple Equation + More Efficient Vehicles Increased Use of Alternative Fuels = A More Energy Independent Nation
Key Elements of the Partnership for a New Generation of Vehicles Daimler Chrysler Ford Suppliers Universities Small Business Federal Labs GM DOC Capabilities Prioritized Needs USCAR Resources Technologies DOT NSF Technologies Government Industry Partnership (PNGV) Goal 1: Adv. Manufacturing Goal 2: Near-Term Vehicle Improvements 3/98 DOE Goal 3: Triple Fuel Efficiency (up to 80 mpg) Technologies Resources Government Agencies (DOC Lead) DOD EPA NASA
PNGV Technology Selection Completed on Schedule 1993 Hybrid Vehicles Fuel Cells, Fuel Reformers CIDI Engines, Turbines Low Emissions Technologies New Materials Advanced Design Simulations Efficient Electronics and Electrical Devices Advanced Batteries Ultra-Capacitors and Flywheels Focus and Accelerate Candidates for Development: Technology Selection Decisions Completed 1997 2000 Three Concept Cars 2004 Three Production Prototype Cars Technology Demo. Vehicles
Results of Technology Selection Process Focus R&D on: Most promising technology areas: hybrid-electric vehicle drive fuel cells direct injection engines lightweight materials Overcoming top technical barriers
Top Technical Barriers NOx and particulate emissions from CIDI engine systems Compact, high-efficiency fuel-flexible fuel processor for PEM fuel cell Thermal management for lithium battery systems Commercial production costs: Lamination material and processing for motor rotors and stators Aluminum sheet, carbon fiber for structural applications, and magnesium Power electronic building blocks and liquid coolants High pressure fuel injector and pump Electrode materials and fabrication processes for batteries and fuel cells
Advanced Automotive Technologies Displayed at International Auto Shows 1999 Detroit Auto Show 1999 Detroit Auto Show Dodge Charger R/T Concept Vehicle - Compressed Natural Gas (CNG) Fueled * - Features Conformable (Flat) CNG Storage System - Reduces CO2 emissions by 25% 1998 Paris Auto Show * * * * Ford P2000 Hybrid Electric Vehicle - Aluminum 1.2L DIATA Diesel Engine - High-power nickel metal hydride battery - Light-weight aluminum intensive body - Automatically shifted manual transmission GM Zafira Fuel Cell Concept Vehicle * - On-board reforming of methanol into hydrogen - Batteries capture braking energy and assist acceleration - Twice the fuel economy of gasoline engine minivan - Reduces CO2 emissions by 50% and NOx by 100% * DOE supported technologies
DaimlerChrysler Fuel Cell Vehicle Development Program
Transportation Technologies Program: Ambitious Goals for Highway Vehicles 2011 100-mpg Automobile 2004 80-mpg Automobile 50% Improved mpg Light Truck 2004 2004 10-mpg 10-mpg Heavy Truck Heavy Truck 2003 Extendedrange EVs 1999 Full-range CNG