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This paper reviews the development of the first fuel economy engine test method for heavy duty diesel oil, as well as the new JASO DH-2F category introduced in April 2017 [1][2][3], which adds a fuel economy requirement to the JASO DH-2 requirements in the JASO M355:2015 standard. Recently, better fuel economy is required heavy duty diesel vehicles as well as gasoline vehicles. Therefore, advanced technologies have been applied to improve diesel engines, as well as diesel engine oils and additives, and achieve better fuel economy. However, the Automotive Diesel Engine Oil Standard (JASO M355) applied in Japan as a standard for diesel engine oils does not include any fuel economy requirements.

The application of biodiesel fuel (BDF) to diesel engines is very effective at reducing CO2 emissions, because biodiesel is considered to be carbon neutral in principle. Gas-to-liquid (GTL) fuel, a synthetic fuel, is expected to reduce emissions from diesel engines. This study focused on the effects of driving conditions and fatty acid methyl ester (FAME) and GTL blended fuel on emissions from diesel engines/vehicles meeting Japan's new short-term regulations, or '03 regulations. FAME including rape methyl ester (RME), palm oil methyl ester (PME) and soybean methyl ester (SME) were studied. Major technologies for emissions reduction may include common-rail high-pressure fuel injection system, cooled exhaust gas recirculation (EGR) system, diesel oxidation catalyst (DOC) and diesel particulate filter (DPF).

Biomass derived ethanol is thought to be a promising gasoline blend stock to reduce carbon dioxide (CO2) emissions from vehicles, and its practical use is under discussion. In Japan, the maximum permissible limit of ethanol content in gasoline is 3 vol%, which almost corresponds to 1.3 mass% of oxygen content, which is defined by gasoline quality standards at present. In addition to ethanol, the use of Ethyl tert-Butyl Ether (ETBE), which is synthesized from biomass ethanol and isobutene, is under discussion as a kind of biomass fuels in Japan. This study examines and discusses the effects of ethanol- and ETBE-blended gasolines on evaporative emissions, especially on refueling loss and diurnal breathing loss (DBL) emissions, from in-use passenger cars in Japan. This study shows that refueling loss emissions don't increase with ethanol- or ETBE-blended gasoline as long as Reid Vapor Pressure (RVP) is adjusted.

Our research objective is to clarify the effect of the utilization of diesel fuels made from unconventional petroleum sources (GTL, Tar Sand, etc.) on the latest vehicle‛s emission and performance. The target properties studied are mainly cetane number and cyclic compounds. Two diesel vehicles and one engine were used in this study. Varieties of transient driving modes were selected for better understanding under real world driving in the emission test. Startability and operability are examined in the vehicle performance test. It was revealed that the tail-pipe emission from a J-2003 reg-compliant vehicle and the engine-out emission from a J-2005 reg-compliant engine used in this study were changed by cetane number and cyclic compound. For J-2003 reg-compliant vehicle, the decrease in cetane number led to the increase in emissions of THC, CO and NOx, while the increase in cyclic compounds led to increase in emissions of PM, THC, CO and NOx.