Abstract
Emission models are important tools for traffic emission and air quality estimates. Existing instantaneous emission models employ the steady-state “engine emissions map” to estimate emissions for individual vehicles. However, vehicle emissions vary significantly, even under the same driving conditions. Variability in the emissions at a specific driving condition depends on various influencing factors. It is important to gain insight into the effects of these factors, to enable detailed modeling of individual vehicle emissions. This study employs a portable emissions measurement system (PEMS), to collect vehicle emissions including the corresponding parameters of engine condition, vehicle activity, catalyst temperature, geography, and meteorology, to analyze the variability in emission rates as a function of those factors, across different vehicle specific power (VSP) categories. We observe that carbon dioxide, carbon monoxide, nitrogen oxides, and particle number emissions are strongly correlated with engine parameters (engine speed, torque, load, and air-fuel ratio) and vehicle activity parameters (vehicle speed and acceleration). In the same VSP bin, emissions per second on highways and ramps are higher than those on arterial roads, and the emissions when the vehicle is traveling downhill tend to be higher than the emissions during uphill traveling, because of higher observed speeds and accelerations. Morning emissions are higher than afternoon emissions, due to lower temperatures.
Highlights
IntroductionCertain operational emission models collect emissions and the corresponding engine parameters (e.g., engine speed, torque, power, and air-fuel ratio) to develop a steady-state “engine emissions map” for each vehicle type
Emission models are important tools for traffic emission and air quality estimates
The emissions of a gasoline direct injection vehicle were tested using a state of the art portable emissions measurement system (PEMS) unit, along two study routes that cover various types of roads and traffic conditions
Summary
Certain operational emission models collect emissions and the corresponding engine parameters (e.g., engine speed, torque, power, and air-fuel ratio) to develop a steady-state “engine emissions map” for each vehicle type. Some models employ vehicle activity parameters such as vehicle speed, acceleration, and vehicle specific power (VSP) [1] to explain emissions. They are categorized based on models that use engine operation data and models that use vehicle activity data. These models calculate average emissions per unit of time, known as emission rates, for different vehicle types and driving conditions, relying on large databases of emission test results (dynamometer and on-road). The emission rates are further used to generate emission inventories at the regional level or the link level for a fleet of vehicles with averaging periods ranging from one hour to one year
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