Turbocharging, increasing the compression ratio, and downsizing a spark-ignition engine are well known strategies for improving vehicle fuel economy. However, such strategies result in higher in-cylinder pressures and temperatures which increase the likelihood of engine knock above that of naturally-aspirated engines. A high octane fuel, such as E85, effectively suppresses knock but the octane ratings of such fuels are much above what is required under normal driving conditions. To address this issue, there have been attempts to use octane more effectively by means of Octane on Demand (OOD): higher octane fuel is used only when needed. Engine experiments were performed to understand the combustion characteristics and knock limits of a commercially available turbocharged spark ignition engine. By utilizing data from engine experiments and engine-in-vehicle simulations, this study quantifies the octane requirement of a 2-liter turbocharged engine over its operating range as well as for various driving cycles. The average octane ratings of fuel needed in real-world driving were in the 60-80 RON range (maximum RON required around 90-100.) Engine configurations (boost/downsizing level, compression ratio), spark retard strategies, and vehicle configurations (vehicle type and loading conditions) were important parameters deciding these octane requirements. To analyze the effects of downsizing, retarding spark timing, increasing compression ratio, and vehicle type on dual fuel applications, GT-power simulation was conducted along with engine experiments and engine-in-vehicle simulations for a passenger vehicle and a medium-duty truck. Parametric studies were conducted to analyze the effects of listed variables on the vehicle fuel consumption, ethanol usage, and average engine efficiency. Downsizing a naturally-aspirated engine by 50% resulted in about a 30% increase in fuel economy. Ethanol consumption varied from 5 to 40% (by volume) of the total fuel used, depending on the details. Moderate amounts of spark retard reduced ethanol consumption by half while not deteriorating fuel economy significantly. Increasing compression ratio above 11.5 had a marginal return in fuel economy while demanding a significantly larger amount of ethanol. Finally, two dual fuel systems (twotank and on-board fuel separation) were modeled to compare benefits and disadvantages. Additionally, a new cycle-by-cycle pressure analysis method is presented, which help better explain the cycle-by-cycle variations of the spark ignition engine combustion process.

Various combinations of commercially available technologies could greatly reduce fuel consumption in passenger cars, sport-utility vehicles, minivans, and other light-duty vehicles without compromising vehicle performance or safety. Assessment of Technologies for Improving Light Duty Vehicle Fuel Economy estimates the potential fuel savings and costs to consumers of available technology combinations for three types of engines: spark-ignition gasoline, compression-ignition diesel, and hybrid. According to its estimates, adopting the full combination of improved technologies in medium and large cars and pickup trucks with spark-ignition engines could reduce fuel consumption by 29 percent at an additional cost of $2,200 to the consumer. Replacing spark-ignition engines with diesel engines and components would yield fuel savings of about 37 percent at an added cost of approximately $5,900 per vehicle, and replacing spark-ignition engines with hybrid engines and components would reduce fuel consumption by 43 percent at an increase of $6,000 per vehicle. The book focuses on fuel consumption-the amount of fuel consumed in a given driving distance-because energy savings are directly related to the amount of fuel used. In contrast, fuel economy measures how far a vehicle will travel with a gallon of fuel. Because fuel consumption data indicate money saved on fuel purchases and reductions in carbon dioxide emissions, the book finds that vehicle stickers should provide consumers with fuel consumption data in addition to fuel economy information.

Whether youre interested in better performance on the road or extra horsepower to be a winner on the track, this book gives you the knowledge you need to get the most out of your engine and its turbocharger system. Find out what works and what doesnt, which turbo is right for your needs, and what type of set-up will give you that extra boost. Bell shows you how to select and install the right turbo, how to prep your engine, test the systems, and integrate a turbo with EFI or carbureted engine.

The light-duty vehicle fleet is expected to undergo substantial technological changes over the next several decades. New powertrain designs, alternative fuels, advanced materials and significant changes to the vehicle body are being driven by increasingly stringent fuel economy and greenhouse gas emission standards. By the end of the next decade, cars and light-duty trucks will be more fuel efficient, weigh less, emit less air pollutants, have more safety features, and will be more expensive to purchase relative to current vehicles. Though the gasoline-powered spark ignition engine will continue to be the dominant powertrain configuration even through 2030, such vehicles will be equipped with advanced technologies, materials, electronics and controls, and aerodynamics. And by 2030, the deployment of alternative methods to propel and fuel vehicles and alternative modes of transportation, including autonomous vehicles, will be well underway. What are these new technologies - how will they work, and will some technologies be more effective than others? Written to inform The United States Department of Transportation's National Highway Traffic Safety Administration (NHTSA) and Environmental Protection Agency (EPA) Corporate Average Fuel Economy (CAFE) and greenhouse gas (GHG) emission standards, this new report from the National Research Council is a technical evaluation of costs, benefits, and implementation issues of fuel reduction technologies for next-generation light-duty vehicles. Cost, Effectiveness, and Deployment of Fuel Economy Technologies for Light-Duty Vehicles estimates the cost, potential efficiency improvements, and barriers to commercial deployment of technologies that might be employed from 2020 to 2030. This report describes these promising technologies and makes recommendations for their inclusion on the list of technologies applicable for the 2017-2025 CAFE standards.

Gasoline - ethanol blends were explored as a strategy to mitigate engine knock, a phenomena in spark ignition engine combustion when a portion of the end gas is compressed to the point of spontaneous auto-ignition. This auto-ignition is dangerous to the operation of an internal combustion engine, as it can severely damage engine components. As engine designers are trying to improve the efficiency of the internal combustion engine, engine knock is a key limiting factor in engine design. Two methods have been used to limit engine knock that will be considered here; retarding the spark timing and addition of additives to reduce the tendency of the fuel mixture to knock. Both have drawbacks. Retarding spark reduces the engine efficiency and additives typically lower the heating value of the fuel, requiring more fuel for a given operating point. To study this problem a turbocharged engine was tested with a variety of combinations of gasoline and ethanol, an additive with very good anti-knock abilities. Pressure was recorded and GT Power simulations were used to determine the temperature within the cylinder. An effective octane number was calculated to measure the ability of the fuel to resist knock. Effective octane numbers varied from 91 for UTG91 to 111 for E25, respectively. Engine simulations were used to extrapolate to points that couldn't be tested in the experimental setup and generate performance maps which could be used to predict how the engine would act inside of a vehicle. It was found that increasing the compression ratio from 9.2 to 13.5 leads to a 7% relative increase in part load efficiency. When applied in a vehicle this leads to a 2-6% increase in miles per gallon of gasoline consumption depending on the drive cycle used. Miles per gallon of ethanol used were significantly higher than gasoline; 141 miles per gallon of ethanol was the lowest mileage over all cycles studied.

Racing continues to provide the preeminent directive for advancing powertrain development for automakers worldwide. Formula 1, World Rally, and World Endurance Championship all provide engineering teams the most demanding and rigorous testing opportunities for the latest engine and technology designs. Turbocharging has seen significant growth in the passenger car market after years of development on racing circuits. Advances in Turbocharged Racing Engines combines ten essential SAE technical papers with introductory content from the editor on turbocharged engine use in F1, WRC, and WEC-recognizing how forced induction in racing has impacted production vehicle powertrains. Topics featured in this book include: Fundamental aspects of design and operation of turbocharged engines Electric turbocharger usage in F1 Turbocharged engine research by Toyota, SwRI and US EPA, Honda, and Caterpillar This book provides a historical and relevant insight into research and development of racing engines. The goal is to provide the latest advancements in turbocharged engines through examples and case studies that will appeal to engineers, executives, instructors, students, and enthusiasts alike.

Increasing pressure on global reserves of petroleum at a time of growing demand for personal transport in developing countries, together with concerns over atmospheric pollution and carbon dioxide emissions, are leading to a requirement for more sustainable forms of road transport. Major improvements in the efficiency of all types of road vehicles are called for, along with the use of fuels derived from alternative sources, or entirely new fuels. Towards Sustainable Road Transport first describes the evolution of vehicle designs and propulsion technologies over the past two centuries, before looking forward to possible new forms of energy to substitute for petroleum. The book also discusses the political and socio-economic drivers for change, investigates barriers to their broad implementation, and outlines the state-of-the-art of candidate power sources, advanced vehicle design, and associated infrastructure. The comprehensive technical informationsupplied by an expert author team ensures that Towards Sustainable Road Transport will provide readers with a clear understanding of the ongoing progress in this field and the challenges still to be faced. - Drivers of technological change in road transport and the infrastructure requirements - Discussion of alternative fuels for internal combustion engines and fuel conversion technologies - Detailed exploration of current and emerging options for vehicle propulsion, with emphasis on hybrid/battery electric traction, hydrogen, and fuel cells - Comparative analysis of vehicle design requirements, primary power source efficiency, and energy storagesystems