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Emission, dispersion and deposition of automotive pollutants
The Science of the Total Enuironment, 33 (1984) 141-145 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
EMISSION,
DISPERSION
AND DEPOSITION
- Preliminary
J.S.
Hooghiemstra,
Agricultural 6700
communication
H.
Harssema
University,
EV
OF AUTOMOTIVE
and
Deparment
Wageningen
(The
141
POLLUTANTS
-
P.
Hofschreuder
of
Air
Pollution,
P.O.
Box
6123,
Netherlands).
SUMMARY The emission of road traffic can be estimated by using a mass-balance technique; this way, an average emission rate, for a given traffic situation, can be found, which is not influenced by the factors that govern emission rates for individual cars. The need for a detailed dataset, which contains dispersion data for both gaseous and particulate pollutants, is pointed out. The instrumental lay-out, which overlaps for both experiments, is described. At present only limited data are available.
EMISSION Estimates tests,
for
traffic
performed
out
by
Bullin
emission into
account
tions,
individual
al
(ref.
which
are
et
rates
emissions
on
factors
are cars,
I),
in
usually in
this
way
representative
like
vehicle
mix,
derived
specified it
from
test is
for
the
state
of
chassis
cycles.
very
difficult
whole
of
dynamometer-
As
is
to the
car
maintenance,
pointed
establish park,
taking
operating
condi-
etc. However,
tion
and
the
emission
road
Using a vertical
individual
principle plane
of are
realistic
of
configuration of
the
upwind sinks
determination
the
of
possible. are
averaged
amount
of
a roadway equal
the
this
-a,
Q
q
minus
material measuring
U
= wind
z,y
= height,
strength
the
amount
emitted
by
occurs),
the
site
during
0 1984
(m/s)
length
Elsevier
(ml
Science
Publishers
a given
situa-
which
influence
factors way. pollutant
(Wms)
velocity
all
a particular
amount
in
a realistic
1
source
traffic
way in
C.u.dydz
-1
”
004%9697/84/$03.00
of
I+"
Q= with
the of
passing
cm
In
is
buffering
cars,
established.
emission
cars,
of
must
or
average
the
downwind roadway
present mix
that
the
B.V.
flowing
flowing the
through
traffic
emission the
through
rate sample
a plane
(provided of time,
no a can
be
142 If
wind
velocities
currents,
wind
and
background
fied
equation
are
higher
directions
are
concentrations can
be
than
low
used
C2.uy;dz
massbalance
an
upwind
At
the
wind
background same
and were
class
between
1500
to
the
same taken
by
Whatman
41
mm/s
lead/km an
large
average
at was
were
1.10,
1.10
m height
one
hour
was
(2)
of
4.50
and the
in
emission as
m and
road-edge. anemometers, vane.
Pasquill
stabili-
a traffic
intensity
obtained
emission
an
and
propeller
mainly and
times
7.50
cup
a Gill
8 m/s
SF6
the
20
highway
10 m from
runs, and
The
85%
car the
sensitive
10 m with
5 m/s
cars/hour.
2.50,
with
at
emitting from
0.70,
measured eight
(2)
a SF6
measured
between
all
emission place
as
mm 0 open
face
47
for
lead f
low
lead same
direction.
content
into
of
thus
based
often
on
far
from
us
DISPERSION
AND DEPOSITION type
pollutant
develop
from
determined
integra-
in
the
physical
processes
emissions,
the
in
physical
any
meaning
as
an must
this
to
Thus,
induced
by
give
et
were and
when the
- experimentally obscure.
type
al set
an
to
1);
their
test
this
description
the
for
itself, - correction
dispersion is,
results,
to
actually
found
results, concept
technique.
estimate
traffic
for
balance
describe
modelling
fuel
itself,
preliminary
mass
9.1 100
potential
roadway
approach
to
of of
sampler
(ref.
own
of
average
the of
lead
sampled
rate
speed
the
up
our the
a fair claim
velocity
36% of
of
evaluate
not
a face
average
this
a statistical
do
was
Assuming is
Bullin
never
to
are
detail.
remain
the
purpose,
program
try
emission
deposition
in
but
g/dm3.
of
which
an
of
aerosol
an emission
of
surprising.
they
0.39
the
not
models
with
with
efficiency
presence
level,
turbulence
expressed
km/h
for
holders
of
concentrations
The
measurements
the
ideal
as
on ground
filter
low
from
samples.
traffic
reported
dispersion
SF6
fuel
100
a field
dispersion,
concentrations
the
measurements
encouraged
Gaussian
to
is are
calculated
the
these
the
and
lead
calculations cases
on km at
3)
was
cruising
account
(ref.
retrieval
From steady
8 dm3/100
Taking
Similar
the
point
the
fitted
particles
models,
0.35,
the
at
deduced
consumption
of
of
velocity
equation
in upward was
emission.
and
10 m downwind
passenger
time
samples
in
driving
during
.dz
2
car.
At
26.5
a simpli-
(C2-C,)uy
by
windspeeds
- 3000
in
the
Z),
according
emission
and
obtained
road
0:
at
-direction
C (ref.
the
concentrations
2
tested
heights
wind
counterto
LX>
located
measuring
heights
velocity
tion
at
induced
perpendicular
downwind
C,.uy,.dz
was tower
tracer
Results ty
concept
the
to
traffic
45"
0:
a measuring
sampling
avoid of
compared
-
0I
past
to
angle
N
Q =
This
an
:
w
hour
1 m/s
within
pollutant occurring of
in factor,
traffic
Gaussian of
type which
mg km/h
143 K-type the
To the
validate
on
this
of
type
pattern
needs
also
as
equation,
processes
models
Gaussian
but
advection-diffusion physical
type
of
road,
the
formulate
concentration the
logical
far
more
models,
for
to
be
a function
in input
data
a given
known,
of
give
are
only
required
than
for
situation
as a function
besides
us
way.
meteorological
not
height,
however,
a mathematical
more
of
distance
extensive
meteoro-
data.
The tion
number of
Most
of
models
notable
in
(ref.
experiments used
very
the
were Long
(SF6),
the
exact
which
allow
evaluation
and
valida-
small.
respect
and
roadways
the
General
Island
from
running
instead
of
the
Sulfate
Dispersion
Experiment
cars
pattern,
knowledge
Motors
Expressway
emitted
a concentration
Of course
of
emission
(re.
along the
5).
the
actual
rate
is
In
road,
both was
traffic
emis-
advantageous
for
put-poses.
It
is
traffic
very
likely
that
emissions some
there
hardly
dispersion a data
particulate
set,
on
particle
deposition
any
studies
and
deposition
and
tracergas
disperses
in
the
dispersion
however
short-term
effects
same
way
will
be
as
the
different
size. on
containing
pollutants
on
used
particulate
dependent
are
establish
the
themselves,
degree,
particulate
data
is this
4)
establish
modelling
As
along
a tracergas
to
sion.
experiments
K-type
Experiment
to
based to
validation
the to
models,
opportunity
the along
roadways,
concentration
patterns
simultaneously
for
meteorological
data.
short
of
the
periods
meteorology
need
was
on
felt
to
of
both
gaseous
and
of
time
- i.e.
1 hour
EXPERIMENTAL The
field
programs
concentration
patterns
programs Site
is : the
site
as
which
is
is
to
road
Instruments:
gas one
Gassamples
are
gaschromatographically. instruments, Fine
aerosol
rod,
is
detail
collected
with
a 50%
cut-off
is
impacted
on
aerosol mounted
in
on
a 12-V
have
with
in
fig.
sequential
1.
of
both
Sampling
in
tower
vertical
B
dispersion,
are
sampled
Vrins
and filter,
diameter
at
Vaseline-coated rotating
multiple-bag
sampling
a Bendix
on a paper
DC motor,
lay-out
estimation.
NO with
by
the
a minimum
4 l/h,
Particulates described
preseparator, Coarse
on
that
complete
one.
presented to
approximately
analysed
establishing
6. is
taken
for
extent, in
emission
are
of
ref.
possible,
a good
samplers
sample
an
and
described
lay-out
as
for
such
be in
the
the
emission
to
will
described
necessary
obtaining hour.
and
lay-out:
close
estimating
overlap
combined
Instrumental is
for
NO/NO, with
(ref. passing at
'Rotorods". at
2400
and
a combination
after pm,
during
monitor,
Hofschreuder
5.5
samplers,
continuously
t/min.
35
on of
the CO,
two
7). through
a cyclone
l/min. A Rotorod
is
a U-shaped
-
144
The
sampling
rate
windtunnel is
6 pm,
while properties
samples.
Sampling atomic
for
instrument,
full
is
days, is
indication
measured
since
particle
been
m3/h.
diameters even
minutes.
the
parts
All
tested The
of
aerosol
extensively
lower
only
50%
in
cut-off
diameter
limitations
insects
can
samples
are
are
be
found
the in
analysed
on
the lead
spectrophotometry. on
level.
the
particle
60
has 7.2
Vaseline;
is
paper
Filters for
The actual
size,
filters
are
shorter
limitative. of
between
the
time
which
approximately
larger
of
on ground
analysis
the
absorption
Deposition placed
this is
for
adhesive
with
of
experiments,
(0
analysed
exposure
deposition on
deposition
the
thus
natural
velocity
mm),
lead.
times date
deposition
135 on
in
small
The
filters
detection
and
surface
windspeed
and
trays, at-e
limit
obtained
surfaces,
flat
give since
of
only the
exposed the
qualitative t-elation
properties
are
extremely
complex. Meteorological temperature with
measurements at
Casella
8 and
include
2 m heigt,
cupanemometers
and
supplemented Young
with
propellor
1.
and
NO from The
information preceeding
program
will
on test be
emission
continued
is
dispersion at 1 and
for
and deposition 20 m (west)
bag sampler), sensor, Y2 C : Casella
and
reported
a period
of
to
fig.
1.
west
rates,dispersion
experiments
10 m height,
measurements
according
road
Instrumental lay-out for emission, ments. Sampling trays for deposition 1, 5, 10, 20 and 50 m (east). Instruments: q : NO + CO (multiple cyclone + Rotorod, T : temperature vane, Y3 : Young propellor bivane,
Limited
at
wind-profile
bivanes,
east IGURE
-direction
and
measureat
o : oarticulates: : Young propellor cupanemometer.
deposition
in
ref.
8.
one
and
a half
of
Years.
lead
145
ACKNOWLEDGEMENTS The
authors
assistance. Dutch
thank The
Ministry
J.
emission of
Housing,
van part
Tongeren of Physical
and the
study Planning
R.
de is
Wit
for
supported and
technical by
a grant
and
analytical from
the
Environment.
REFERENCES 1 2 3 4 5 6 7 8
J.A. Bullin et al, Determination of vehicle emission rates from roadways bv mass balance techniaues. Env. Sci. Technol. 14 (1980) 700-705. F". Pasquill, Atmospheric diffusion. Wiley, New York (1974). Barrett et al, Proceedings VIth World Congress on Air Quality, Vol. 1 (1983) 305-311. S.H. Cadle et al, General Motors Sulfate Dispersion Experiment: experimental procedures and results. JAPCA 27 (1977) 33-38. S.T. Roa et al, Characteristics of turbulence and dispersion of pollutants near major highways. J. Appl. Met. 18 (1979) 283-293. J.S. Hooghiemstra et al, Long term concentrations of nitrogen oxides along a highway - in this volume E. Vrins and P. Hofschreuder, Sampling total suspended particulate matter. Proceedings GAF-Conference, Bologna (1982). Emission, dispersion and deposition of P. Hofschreuder and H. Harssema, automotive pollution. Proc. VIth World Congress on Air Pollution Paris, 4 (1983) 113-119.
EMISSION,
DISPERSION
AND DEPOSITION
- Preliminary
J.S.
Hooghiemstra,
Agricultural 6700
communication
H.
Harssema
University,
EV
OF AUTOMOTIVE
and
Deparment
Wageningen
(The
141
POLLUTANTS
-
P.
Hofschreuder
of
Air
Pollution,
P.O.
Box
6123,
Netherlands).
SUMMARY The emission of road traffic can be estimated by using a mass-balance technique; this way, an average emission rate, for a given traffic situation, can be found, which is not influenced by the factors that govern emission rates for individual cars. The need for a detailed dataset, which contains dispersion data for both gaseous and particulate pollutants, is pointed out. The instrumental lay-out, which overlaps for both experiments, is described. At present only limited data are available.
EMISSION Estimates tests,
for
traffic
performed
out
by
Bullin
emission into
account
tions,
individual
al
(ref.
which
are
et
rates
emissions
on
factors
are cars,
I),
in
usually in
this
way
representative
like
vehicle
mix,
derived
specified it
from
test is
for
the
state
of
chassis
cycles.
very
difficult
whole
of
dynamometer-
As
is
to the
car
maintenance,
pointed
establish park,
taking
operating
condi-
etc. However,
tion
and
the
emission
road
Using a vertical
individual
principle plane
of are
realistic
of
configuration of
the
upwind sinks
determination
the
of
possible. are
averaged
amount
of
a roadway equal
the
this
-a,
Q
q
minus
material measuring
U
= wind
z,y
= height,
strength
the
amount
emitted
by
occurs),
the
site
during
0 1984
(m/s)
length
Elsevier
(ml
Science
Publishers
a given
situa-
which
influence
factors way. pollutant
(Wms)
velocity
all
a particular
amount
in
a realistic
1
source
traffic
way in
C.u.dydz
-1
”
004%9697/84/$03.00
of
I+"
Q= with
the of
passing
cm
In
is
buffering
cars,
established.
emission
cars,
of
must
or
average
the
downwind roadway
present mix
that
the
B.V.
flowing
flowing the
through
traffic
emission the
through
rate sample
a plane
(provided of time,
no a can
be
142 If
wind
velocities
currents,
wind
and
background
fied
equation
are
higher
directions
are
concentrations can
be
than
low
used
C2.uy;dz
massbalance
an
upwind
At
the
wind
background same
and were
class
between
1500
to
the
same taken
by
Whatman
41
mm/s
lead/km an
large
average
at was
were
1.10,
1.10
m height
one
hour
was
(2)
of
4.50
and the
in
emission as
m and
road-edge. anemometers, vane.
Pasquill
stabili-
a traffic
intensity
obtained
emission
an
and
propeller
mainly and
times
7.50
cup
a Gill
8 m/s
SF6
the
20
highway
10 m from
runs, and
The
85%
car the
sensitive
10 m with
5 m/s
cars/hour.
2.50,
with
at
emitting from
0.70,
measured eight
(2)
a SF6
measured
between
all
emission place
as
mm 0 open
face
47
for
lead f
low
lead same
direction.
content
into
of
thus
based
often
on
far
from
us
DISPERSION
AND DEPOSITION type
pollutant
develop
from
determined
integra-
in
the
physical
processes
emissions,
the
in
physical
any
meaning
as
an must
this
to
Thus,
induced
by
give
et
were and
when the
- experimentally obscure.
type
al set
an
to
1);
their
test
this
description
the
for
itself, - correction
dispersion is,
results,
to
actually
found
results, concept
technique.
estimate
traffic
for
balance
describe
modelling
fuel
itself,
preliminary
mass
9.1 100
potential
roadway
approach
to
of of
sampler
(ref.
own
of
average
the of
lead
sampled
rate
speed
the
up
our the
a fair claim
velocity
36% of
of
evaluate
not
a face
average
this
a statistical
do
was
Assuming is
Bullin
never
to
are
detail.
remain
the
purpose,
program
try
emission
deposition
in
but
g/dm3.
of
which
an
of
aerosol
an emission
of
surprising.
they
0.39
the
not
models
with
with
efficiency
presence
level,
turbulence
expressed
km/h
for
holders
of
concentrations
The
measurements
the
ideal
as
on ground
filter
low
from
samples.
traffic
reported
dispersion
SF6
fuel
100
a field
dispersion,
concentrations
the
measurements
encouraged
Gaussian
to
is are
calculated
the
these
the
and
lead
calculations cases
on km at
3)
was
cruising
account
(ref.
retrieval
From steady
8 dm3/100
Taking
Similar
the
point
the
fitted
particles
models,
0.35,
the
at
deduced
consumption
of
of
velocity
equation
in upward was
emission.
and
10 m downwind
passenger
time
samples
in
driving
during
.dz
2
car.
At
26.5
a simpli-
(C2-C,)uy
by
windspeeds
- 3000
in
the
Z),
according
emission
and
obtained
road
0:
at
-direction
C (ref.
the
concentrations
2
tested
heights
wind
counterto
LX>
located
measuring
heights
velocity
tion
at
induced
perpendicular
downwind
C,.uy,.dz
was tower
tracer
Results ty
concept
the
to
traffic
45"
0:
a measuring
sampling
avoid of
compared
-
0I
past
to
angle
N
Q =
This
an
:
w
hour
1 m/s
within
pollutant occurring of
in factor,
traffic
Gaussian of
type which
mg km/h
143 K-type the
To the
validate
on
this
of
type
pattern
needs
also
as
equation,
processes
models
Gaussian
but
advection-diffusion physical
type
of
road,
the
formulate
concentration the
logical
far
more
models,
for
to
be
a function
in input
data
a given
known,
of
give
are
only
required
than
for
situation
as a function
besides
us
way.
meteorological
not
height,
however,
a mathematical
more
of
distance
extensive
meteoro-
data.
The tion
number of
Most
of
models
notable
in
(ref.
experiments used
very
the
were Long
(SF6),
the
exact
which
allow
evaluation
and
valida-
small.
respect
and
roadways
the
General
Island
from
running
instead
of
the
Sulfate
Dispersion
Experiment
cars
pattern,
knowledge
Motors
Expressway
emitted
a concentration
Of course
of
emission
(re.
along the
5).
the
actual
rate
is
In
road,
both was
traffic
emis-
advantageous
for
put-poses.
It
is
traffic
very
likely
that
emissions some
there
hardly
dispersion a data
particulate
set,
on
particle
deposition
any
studies
and
deposition
and
tracergas
disperses
in
the
dispersion
however
short-term
effects
same
way
will
be
as
the
different
size. on
containing
pollutants
on
used
particulate
dependent
are
establish
the
themselves,
degree,
particulate
data
is this
4)
establish
modelling
As
along
a tracergas
to
sion.
experiments
K-type
Experiment
to
based to
validation
the to
models,
opportunity
the along
roadways,
concentration
patterns
simultaneously
for
meteorological
data.
short
of
the
periods
meteorology
need
was
on
felt
to
of
both
gaseous
and
of
time
- i.e.
1 hour
EXPERIMENTAL The
field
programs
concentration
patterns
programs Site
is : the
site
as
which
is
is
to
road
Instruments:
gas one
Gassamples
are
gaschromatographically. instruments, Fine
aerosol
rod,
is
detail
collected
with
a 50%
cut-off
is
impacted
on
aerosol mounted
in
on
a 12-V
have
with
in
fig.
sequential
1.
of
both
Sampling
in
tower
vertical
B
dispersion,
are
sampled
Vrins
and filter,
diameter
at
Vaseline-coated rotating
multiple-bag
sampling
a Bendix
on a paper
DC motor,
lay-out
estimation.
NO with
by
the
a minimum
4 l/h,
Particulates described
preseparator, Coarse
on
that
complete
one.
presented to
approximately
analysed
establishing
6. is
taken
for
extent, in
emission
are
of
ref.
possible,
a good
samplers
sample
an
and
described
lay-out
as
for
such
be in
the
the
emission
to
will
described
necessary
obtaining hour.
and
lay-out:
close
estimating
overlap
combined
Instrumental is
for
NO/NO, with
(ref. passing at
'Rotorods". at
2400
and
a combination
after pm,
during
monitor,
Hofschreuder
5.5
samplers,
continuously
t/min.
35
on of
the CO,
two
7). through
a cyclone
l/min. A Rotorod
is
a U-shaped
-
144
The
sampling
rate
windtunnel is
6 pm,
while properties
samples.
Sampling atomic
for
instrument,
full
is
days, is
indication
measured
since
particle
been
m3/h.
diameters even
minutes.
the
parts
All
tested The
of
aerosol
extensively
lower
only
50%
in
cut-off
diameter
limitations
insects
can
samples
are
are
be
found
the in
analysed
on
the lead
spectrophotometry. on
level.
the
particle
60
has 7.2
Vaseline;
is
paper
Filters for
The actual
size,
filters
are
shorter
limitative. of
between
the
time
which
approximately
larger
of
on ground
analysis
the
absorption
Deposition placed
this is
for
adhesive
with
of
experiments,
(0
analysed
exposure
deposition on
deposition
the
thus
natural
velocity
mm),
lead.
times date
deposition
135 on
in
small
The
filters
detection
and
surface
windspeed
and
trays, at-e
limit
obtained
surfaces,
flat
give since
of
only the
exposed the
qualitative t-elation
properties
are
extremely
complex. Meteorological temperature with
measurements at
Casella
8 and
include
2 m heigt,
cupanemometers
and
supplemented Young
with
propellor
1.
and
NO from The
information preceeding
program
will
on test be
emission
continued
is
dispersion at 1 and
for
and deposition 20 m (west)
bag sampler), sensor, Y2 C : Casella
and
reported
a period
of
to
fig.
1.
west
rates,dispersion
experiments
10 m height,
measurements
according
road
Instrumental lay-out for emission, ments. Sampling trays for deposition 1, 5, 10, 20 and 50 m (east). Instruments: q : NO + CO (multiple cyclone + Rotorod, T : temperature vane, Y3 : Young propellor bivane,
Limited
at
wind-profile
bivanes,
east IGURE
-direction
and
measureat
o : oarticulates: : Young propellor cupanemometer.
deposition
in
ref.
8.
one
and
a half
of
Years.
lead
145
ACKNOWLEDGEMENTS The
authors
assistance. Dutch
thank The
Ministry
J.
emission of
Housing,
van part
Tongeren of Physical
and the
study Planning
R.
de is
Wit
for
supported and
technical by
a grant
and
analytical from
the
Environment.
REFERENCES 1 2 3 4 5 6 7 8
J.A. Bullin et al, Determination of vehicle emission rates from roadways bv mass balance techniaues. Env. Sci. Technol. 14 (1980) 700-705. F". Pasquill, Atmospheric diffusion. Wiley, New York (1974). Barrett et al, Proceedings VIth World Congress on Air Quality, Vol. 1 (1983) 305-311. S.H. Cadle et al, General Motors Sulfate Dispersion Experiment: experimental procedures and results. JAPCA 27 (1977) 33-38. S.T. Roa et al, Characteristics of turbulence and dispersion of pollutants near major highways. J. Appl. Met. 18 (1979) 283-293. J.S. Hooghiemstra et al, Long term concentrations of nitrogen oxides along a highway - in this volume E. Vrins and P. Hofschreuder, Sampling total suspended particulate matter. Proceedings GAF-Conference, Bologna (1982). Emission, dispersion and deposition of P. Hofschreuder and H. Harssema, automotive pollution. Proc. VIth World Congress on Air Pollution Paris, 4 (1983) 113-119.