AUTOMOBILE EMISSIONS: AN OVERVIEW
Cars and
Pollution
Emissions from an individual car are generally low,
relative to the smokestack image many people associate with air pollution. But
in numerous cities across the country, the personal automobile is the single
greatest polluter, as emissions from millions of vehicles on the road add up.
Driving a private car is probably a typical citizen's most "polluting" daily
activity.
Sources of Auto Emissions
The power to move a car
comes from burning fuel in an engine. Pollution from cars comes from by-products
of this combustion process (exhaust) and from evaporation of the fuel
itself.
The Combustion Process
Gasoline and diesel fuels
are mixtures of hydrocarbons, compounds which contain hydrogen and carbon atoms.
In a "perfect" engine, oxygen in the air would convert all the hydrogen in the
fuel to water and all the carbon in the fuel to carbon dioxide. Nitrogen in the
air would remain unaffected. In reality, the combustion process cannot be
"perfect," and automotive engines emit several types of
pollutants.
"Perfect" Combustion
FUEL (hydrocarbons) + AIR
(oxygen and nitrogen) ==> CARBON DIOXIDE + water + unaffected
nitrogen
Typical Engine Combustion
FUEL + AIR
==>UNBURNED HYDROCARBONS+ NITROGEN OXIDES + CARBON MONOXIDE + CARBON DIOXIDE
+ water
Exhaust Pollutants
Hydrocarbon emissions result when fuel molecules
in the engine do not burn or burn only partially. Hydrocarbons react in the
presence of nitrogen oxides and sunlight to form ground-level ozone, a major
component of smog. Ozone irritates the eyes, damages the lungs, and aggravates
respiratory problems. It is our most widespread and intractable urban air
pollution problem. A number of exhaust hydrocarbons are also toxic, with the
potential to cause cancer.
NITROGEN OXIDES (NOx). Under the high pressure and
temperature conditions in an engine, nitrogen and oxygen atoms in the air
react to form various nitrogen oxides, collectively known as NOx. Nitrogen
oxides, like hydrocarbons, are precursors to the formation of ozone. They also
contribute to the formation of acid rain.
CARBON MONOXIDE. Carbon monoxide (CO) is a product of
incomplete combustion and occurs when carbon in the fuel is partially oxidized
rather than fully oxidized to carbon dioxide (CO(). Carbon monoxide reduces
the flow of oxygen in the bloodstream and is particularly dangerous to persons
with heart disease.
CARBON DIOXIDE. In recent years, the U.S. Environmental
Protection Agency (EPA) has started to view carbon dioxide, a product of
"perfect" combustion, as a pollution concern. Carbon dioxide does not directly
impair human health, but it is a "greenhouse gas" that traps the earth's heat
and contributes to the potential for global warming.Evaporative
Emissions
Hydrocarbon pollutants also escape into the air through
fuel evaporation. With today's efficient exhaust emission controls and today's
gasoline formulations, evaporative losses can account for a majority of the
total hydrocarbon pollution from current model cars on hot days when ozone
levels are highest. Evaporative emissions occur several
ways;
DIURNAL:Gasoline evaporation increases as the temperature
rises during the day, heating the fuel tank and venting gasoline
vapors.
RUNNING LOSSES: The hot engine and exhaust system can
vaporize gasoline when the car is running.
HOT SOAK: The engine
remains hot for a period of time after the car is turned off, and gasoline
evaporation continues when the car is parked.
REFUELING: Gasoline
vapors are always present in fuel tanks. These vapors are forced out when the
tank is filled with liquid fuel.
What Has Been Done to Control
Automobile Emissions?
The Clean Air Act of 1970 gave EPA broad
authority to regulate motor vehicle pollution, and the Agency's emission control
policies have become progressively more stringent since the early
1970's.
EPA standards dictate how much pollution autos may emit but auto
makers decide how to achieve the pollution limits. The emission reductions of
the 1970's came about because of fundamental improvements in engine design, plus
the addition of charcoal canisters to collect hydrocarbon vapors and exhaust gas
recirculation valves to reduce nitrogen oxides.
The advent of "first
generation" catalytic converters in 1975 significantly reduced hydrocarbon and
carbon monoxide emissions. The use of converters provided a huge indirect
benefit as well. Because lead inactivates the catalyst, 1975 saw the widespread
introduction of unleaded gasoline. This resulted in dramatic reductions in
ambient lead levels and alleviated many serious environmental and human health
concerns associated with lead pollution.
The next major milestone in
vehicle emission control technology came in 1980-81. In response to tighter
standards, manufacturers equipped new cars with even more sophisticated emission
control systems. These systems generally include a "three-way" catalyst (which
converts carbon monoxide and hydrocarbons to carbon dioxide and water, and also
helps reduce nitrogen oxides to elemental nitrogen and oxygen), plus an on-board
computer and oxygen sensor. This equipment helps optimize the efficiency of the
catalytic converter.
Vehicle emissions are being further reduced by
provisions of the 1990 Clean Air Act. Mobile source provisions include even
tighter tailpipe standards, increased durability, improved control of
evaporative emissions, and computerized diagnostic systems that identify
malfunctioning emission controls.
What Has Emission Control Meant for
Air Quality?
Efforts by government and industry since 1970 have
greatly reduced typical vehicle emissions. In those same years, however, the
number of miles we drive has more than doubled. The increase in travel has
offset much of the emission control progress.
The net result is a modest
reduction in each automotive pollutant except lead, for which aggregate
emissions have dropped by more than 95 percent.
With ozone continuing to
present a persistent urban air pollution problem, future vehicle emission
control programs will emphasize hydrocarbon and nitrogen oxide reductions.
Carbon monoxide control will remain critical in many cities, and limits on
vehicle-generated carbon dioxide may become important in the
future.
For Further Information:
The EPA National Vehicle
and Fuel Emissions Laboratory is the national center for research and policy
related to mobile source pollution. Write the lab at 2565 Plymouth Road, Ann
Arbor, MI 48105, or call 313-668-4333.
Source: US EPA
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Last Update - 21-Mar-97