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The world-wide commercial vehicle industry is faced with numerous challenges to reduce oil consumption and greenhouse gases, meet stringent emissions regulations, provide customer value, and improve safety. This work focuses on the new U.S. regulation of greenhouse gas (GHG) emissions from commercial vehicles and diesel engines and the most likely technologies to meet future anticipated standards while improving transportation freight efficiency. In the U.S., EPA and NHTSA have issued a joint proposed GHG rule that sets limits for CO2 and other GHGs from pick-up trucks and vans, vocational vehicles, semi-tractors, and heavy duty diesel engines. This paper discusses and compares different technologies to meet GHG regulations for diesel engines based on considerations of cost, complexity, real-world fidelity, and environmental benefit.

The paper describes a process for the design of fuel-efficient diesel engine powertrains for heavy-duty commercial vehicles. A System Engineering approach is described that delivers optimal fuel efficiency by taking into account interactions among engine, exhaust aftertreatment, and vehicle systems. The primary objective of this approach is to develop a properly integrated system that delivers the lowest total cost of ownership (TCO) while maintaining high sociability, reliability, and performance. The paper will also discuss the role of competitive analysis and benchmarking, in-use duty-cycle analysis, design, simulation and final confirmation tests. System optimization is performed at critical steps in the process for engine hardware, control software and calibration, aftertreatment, engine accessories, powertrain components and vehicle interfaces.