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Vehicle Efficiency Pathways. How modern passenger cars are removing themselves from the environmental debate . John Bucknell GM Powertrain. Abstract.
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Vehicle Efficiency Pathways How modern passenger cars are removing themselves from the environmental debate John Bucknell GM Powertrain
Abstract Modern passenger cars must respond to market demand and regulation forces, delivering superior air quality, utmost safety and ever-higher energy efficiency. This lecture will discuss efficiencies on both the supply and demand pathways for improving energy efficiency in the context of emissions and safety regulations. Well-to-wheel and pump-to-wheel efficiencies will also be covered in brief to highlight the efficiency of Electric Vehicles
Topics • Transportation Efficiency • State of the industry • Supply-side Efficiency • Powertrain Efficiency • Driveline Efficiency • Load-leveling • Demand-side efficiency • Aero, rolling-resistance, inertia • Electric Vehicles & Fuel-Cell Vehicles • Pump-to-wheels, well-to-wheels
Market Economics • Cost of ownership • Market demand has illustrated that customers will purchase what they can afford. Technologies that increase cost of ownership have great difficulty penetrating the market. • Energy Costs • Dual impact of increasing environmentalism and increasing energy costs have raised the visibility of vehicle efficiency. • Low energy cost of petroleum products has been the primary factor that has driven the market into a near monoculture for it’s energy needs.
Transportation Efficiency • State of the industry • Economies of scale drive allow manufacturers to compete on cost. Any technology that cannot make a component at a minimum rate of one per minute requires additional sets of tooling, driving up investment and increasing the number of sales to break even. • Profit margins in the automotive industry are exceptionally small, as you’d expect with strong competition for a very large revenue stream. • State of the world has changed rapidly – developing new technologies that are sufficiently robust to be used by every consumer can take a decade or more. The industry is responding to the need for greater efficiency, vehicles on the market today are just the beginning.
Regulation • Tailpipe Emissions • Air quality has been driven by the EPA and the California Air Resources Board. Details on how emittants are formed and regulated follow. • Passenger safety • Customer awareness of impact performance on standardized tests has driven the industry to achieve a minimum “Four star” rating in any test. The degree that of likelihood of injury to achieve the best rating has decreased significantly over the last ten years. High strain-energy density materials, and large masses of them have driven up body structure mass by about double in the same time frame.
Typical 1960 Vehicle (pre-control) 1971 California Std. 1983 Federal Tier 0 1977 Federal Std. Federal Tier 1 NLEV LEV2 ULEV2 SULEV2 Emissions Standards 1960 to 2008 99.99% Reduction
Exhaust Aftertreatment • Catalysts have the capability of modifying the reaction rates of chemical processes (typically increasing reaction rates) without being consumed while doing so. • The following chemical processes are of interest in automotive exhaust catalytic aftertreatment • HC + O2CO2 + H2O • CO + O2 CO2 • NO N2 + O2 • These reactions proceed toward equilibrium at very slow rates at prevailing exhaust temperatures - catalysts increase their reaction rates to a degree that the exhaust aftertreatment becomes practical. • Conversion efficiency: (inlet concentration - outlet concentration)/inlet concentration
Essential Components of a Catalytic Converter Substrate Can Mat Washcoat Catalysts Substrate: a ceramic honeycomb-like structure with thousands of parallel channels for applications of washcoat and catalysts Mat: Provides thermal insulation and protects against mechanical shock and chassis vibration Can: A metal package encasing the catalyzed substrate and mat Washcoat: a coating that increases the surface area of the substrate for catalysis Source: Corning (2001)
Catalysts for Exhaust Aftertreatment The active catalytic material is typically a blend of platinum, palladium, rhodium and nickel. Small amounts of these materials are distributed on a alumina (Al2O3) washcoat, which is specially processed to have very high microscopic surface area. The high washcoat surface area helps to keep the catalytic material spread out to reduce the tendency to agglomerate and thus loose surface area. Cerium oxide is often added to this mix to mechanically stabilize the alumina microstructure against thermal degradation. Typically there are 0.5-2 grams of catalytic material per liter of overall catalyst volume, and the overall catalyst volume is about 50 ~ 80% of the engine displacement, depending on the application.
Temperature Effects on Catalyst Capabilities Catalyst efficiency at catalyst temperatures below 200oC is extremely low. Catalyst efficiency rapidly increases as its temperature rises above 200oC and reaches its temperature plateau at about 400oC. Light-off temperature: conversion efficiency reaches 50% Current exhaust system design practice insures catalyst light-off within ~ 20 seconds without special aids. Catalyst heating devices in lowest emissions vehicles can achieve light-off in under 10 seconds. Source: Heywood (1988)
Catalyst Efficiency with Air/Fuel Ratio Steady improvements in fuelling control, engine-out emissions and catalyst technology has made it possible to achieve 100% conversion rates of HC and NOx after catalyst light-off. Source: Heywood (1988)
Emissions Summary Fuel-burning engines create pollutants that are regulated - which are ever-more stringent. Emissions-control technology has evolved to the point where three-way catalysts are 100% efficient in converting HC, NOx and CO – only if the feedgas operates very close to stoichimetric air-fuel ratio. Any lean-burning combustion process (Diesel or stratified charge) which improves fuel consumption also prevents catalytic NOx reduction by maintaining oxygen in the exhaust stream. Several technologies are emerging which consume fuel or reductant to purge Lean NOx Traps, at the cost of fuel consumption or added complexity.
Supply-Side Efficiency Energy conversation pathway • Powertrain Efficiency (Stratified Charge/HCCI, Downsizing/Boosting) • Driveline Efficiency (Multi-speed Transmissions, CVTs) • Load-leveling (stop-start, mild hybrid, series and parallel hybrids)
Energy Distribution in Passenger Car Engines Source: SAE 2000-01-2902 (Ricardo)
Modern Naturally Aspirated Brake Thermal Efficiency Map Fraction Maximum Torque Fraction Thermal Efficiency Fraction Maximum Engine Speed
Compression vs Spark Ignition Compression ignition achieves significantly higher compression ratios than spark ignition – raising thermal efficiency Spark ignition engines control load by throttling, introducing parasitic losses at less than maximum load which reduces thermal efficiency Smoke limits reduce power density of diesel engines to only about 80% of energy density of spark ignited of similar displacement. High operating pressures require heavy construction which further lowers power/weight ratio Source: Heisler (1995)
Powertrain Efficiency Pathways - Engine - • Prior three slides show that the maximum fraction of fuel energy that reaches the brake is 30-40% of the fuel input energy, which is the most that thermodynamics allows. • Spark ignition engines pay a loss to reduce load by throttling – which is effectively operating a vacuum pump. Several technologies seek to reduce or eliminate pumping work: • Exhaust Gas Recirculation (EGR) – load reduction by diluting incoming combustion air • Variable valve timing (including cam phasers and variable lift/duration systems) – load reduction by reducing trapping efficiency and adding residual (internal EGR) • Stratified Charge with unthrottled operation – load control via fuel mass running lean • Homogeneous Charge Compression Ignition (HCCI) – load control via fuel mass and residual preventing lean operation • Downsizing/Boosting – Reduction in displacement of engine so use of lowest efficiencies is mostly avoided and then boosting to enhance available load
Powertrain Efficiency Pathways - Driveline - • Knowing that an internal combustion engine is most efficient in a limited regime, the driveline can be optimized to enable engine operation the least amount of time away from that regime. • Multi-speed Transmissions – 6, 7, 8 speeds with ratio ranges from 5.0-6.0 give powertrain controller best option of matching engine to current power demand • Continuously Variable Transmissions – Same as multi-speed transmissions, but typically have high parasitic losses • Load Leveling – Through use of onboard energy storage (electric or other), energy conversion can happen at most efficient point in map. Hybrids achieve this through several different strategies – parallel, series or dual-mode are most-often discussed. Micro-hybridization also appearing due to low cost of implementation.
Load-Leveling Engine Stop Start (ESS) • Eliminates fuel consumed during deceleration and idle Fuel On Fuel Off Source: SAE 2001-01-0326 (GM)
Load-Leveling Mild Hybrid • Regenerative Braking, Load-Leveling and Idle Stop Source: SAE 2006-01-1502 (GM)
Load-Leveling Strong Hybrid • Electric-only operation, Regenerative Braking, Load-Leveling and Idle Stop • Parallel, Series and Two-Mode e-CVTs
Demand-Side Efficiency • Not a true ‘efficiency’, however losses that are not minimized could be considered ‘in-efficient’ • Major Components • Inertia Loads (Kinetic Energy) • Aerodynamics • Rolling Resistance
Demand-Side Efficiency • Inertia Loads • Vehicle mass requires proportional power to accelerate. Vehicle duty cycles with greater time spent accelerating will be more sensitive to vehicle mass. • Aerodynamics • Pressure drag: The loss due to the difference in pressure on the front face versus the rear face of the vehicle. The dynamic pressure (also called stagnation pressure) on the leading face is a measure of the kinetic energy of the displaced air. • Friction drag: Losses due to viscosity effects are also substantial. Boundary layer theory says that particles immediately next to a vehicle must be moving at vehicle speed as compared to at the free stream velocity. The shear force created by the relative velocity of the fluid is proportional to vehicle speed and ‘wetted’ surface area moving through the fluid. • The two speed-dependent components cause aerodynamic drag to increase primarily with the square of vehicle speed
Demand-Side Efficiency • Rolling-resistance • Driveline: Seals, bearings, gears, CV and Cardon (universal) joints • Any component using a viscous fluid to reduce contact stress for increased durability also suffers the losses of viscous shear forces regardless of the load. • Brakes • Friction brakes work by rubbing two components together. Unfortunately due to the balancing of pad retraction and response time, disc brakes will drag the pads against the rotors – a little or a lot depending on the design. Drum brakes by their nature have very little hydraulic volume and thus can retract far enough to not drag.
Demand-Side Efficiency • Rolling-resistance • Tires • Part of the suspension isolating the vehicle from surface irregularities. Tire is both a spring and a damper, with greater spring rate and lesser damping force with lesser sidewall height. Spring rate is proportional to inflation pressure. Greater isolation drives greater sidewall and lower pressure. • Inflation pressure is same as tire contact pressure. Contact area is proportional to mass supported by the tire. The greater the contact area, the more rubber has to deflect as it tracks across the surface. Increased tire diameter decreases the degree of deflection. Rubber is not perfectly elastic, so some energy is lost. • The force to roll a tire is therefore proportional to the normal force and the volume of rubber deflected per second which is proportional to rotational velocity.
Measuring Vehicle Efficiency • EPA and real world fuel economy (Efficiency) is impacted by the vehicle’s drag force. Drag is determined by taking a vehicle to 70 mph and then shifting into neutral and measuring speed versus time and thus deceleration rate. Knowing the mass of the vehicle, a drag force versus vehicle speed can be derived. This drag force data is fitted to a 2nd-order polynomial whose coefficients are published by the EPA – called the ABC coefficients. • The chassis dyno where emissions and fuel economy data is taken has • Rollers instead of pavement, with vehicle strapped down • Only drive-wheels turning • No aerodynamic loading • The A,B,C coefficients determine the load which the dyno program must match over the course of the test cycle
Vehicle Drag Force Example A = 28.73 lb B = 0.7338 lb/mph C = 0.01084 lb/mph^2
Evidence of Vehicle Efficiency • EPA data shows that there is no magic. Following slides show every vehicle for sale in 2008 Model Year in the US.
Aero 0.21 Accessories 0.17 Rolling 0.34 Engine D/L Kinetic Engine Losses 5.97 Driveline Losses 0.25 Braking 0.45 Typical Mid-Size Vehicle Energy Distribution Idle 0.90 8.29 units 1.25 1.00 Urban Federal Test Procedure (FTP)
Well-to-Wheels and Tank-to-Wheels • Any true discussion of energy diversity and it’s impact on GHG must discuss the source of energy (ie the Well) • Electric Vehicles will receive the bulk of their energy from coal-fired generation for foreseeable future • Coal-fired electrical generation was 35% thermally efficient in 2005 (EPA) • Line-losses and battery/e-motor efficiency aren’t 0% • Therefore from a GHG perspective -TNSTAAFL
By 2020,1.1 billion vehicles (an increase of 300 million) will circle the earth 125 times.Energy diversity is required in the future. Reducing dependence on petroleum is imperative.
“At GM, we believe tomorrow’s automobiles must be flexible enough to accommodate many different energy sources.” “ And a key part of that flexibility will be enabled by the development of electrically driven cars.” - Rick Wagoner Chairman and CEO General Motors Corporation LA Auto Show 11/29/2006
Hybrid, Electric & Fuel Cell Vehicles Introduction & Background – More definitions Electrification
Conventional ICE: Gasoline/Diesel Plug-In Hybrid (Non-Conventional) Oil Mild and Full Hybrids Biomass Fischer Tropsch Coal Syngas CO, H2 More Electrification CCGT Natural Gas Battery Energy Storage Renewables(Solar, Wind, Hydro) Shift Reaction Nuclear Hydrogen CO2 Sequestration FC Electric Vehicle Transportation Challenge – Energy Diversity - Source Blending via Electrification Energy Resource Conversion Energy Carrier Propulsion System Energy Resource Conversion Energy Carrier Propulsion System Oil (Conventional) Petroleum Fuels Liquid Fuels 1st & 2nd Generation Biofuels Electricity Extended Range EV Electrolysis Battery Electric Vehicle Thermochemical Water-Splitting
Transportation Challenge – Energy Diversity - Source Blending via Electrification