NITROGEN OXIDES REDUCTION 753
Conversion of Emission StandardsAs can be seen from the above regulations, NO x standards
come in various units. Some regulations state NO x limits in
ppm, on a dry volume basis, whereas other regulations may
require the emissions in lbs NO x /MBtu. Figures 2–4 have
been developed for converting emission units at different
oxygen percents in the flue gas for natural gas, oil, and coal
fired units, respectively. Figure 2 is based on a typical gaseous
fuel, a US/Texas gas (see Table 10 18,19 ). Figures 3 and 4 were
based on a number of different liquid and solid fuels (see
Tables 11 18,20 and 12 18,21 , respectively). Three Lotus spread-
sheets were utilized to develop Figure 2. First, a spreadsheet
was developed, Table 13, that converts the gas components,
on a percent volume basis, to the elemental component mass
fractions. In addition, the spreadsheet also calculates the
lower and higher heating values of the natural gas based on
the components in the natural gas. The lower heating value
is compared for accuracy to experimental results. Next, the
component mass fractions were read into the second spread-
sheet, Table 14, to calculate the flue gas constituents and
the pounds of flue gas produced per pound of fuel on a dry
weight basis. Using the quantity of flue gas and the higher
heating value of the natural gas, a “K” factor was developed
for all three figures via:KHHV V
FG MW= × M
×where
HHV heating value of the natural gas, Btu/lb
FG volume of flue gas per lb of fuel, dscf/lb
MW molecular weight of NO 2 , lb/lbmol
V M molar volume, dscf/lbmolIn this equation, V M is equal to 385.1 dscf/lbmol at 68F and
29.92 in. Hg. The “K” factors for a new selected fuels are
found in Tables 10–12. As can be seen from the tables, the
“K” factors do not vary widely for each type of fuel, which
implies that Figures 2–4 could be readily applied to a par-
ticular fuel type. The exception to the rule are gaseous fuels
that have a moderately high carbon dioxide content, such
as the natural gas from Germany. Because the carbon diox-
ide does not play a role in the combustion process, a high
carbon dioxide content gas will produce significantly lower
flue gas per pound of fuel, thereby increasing the “K” factor.
The “K” factor was then read into the third spreadsheet to be
used in the following equation to develop the data points for
each conversion graph:XK E (20.9 %O )
20.9 ^2where
X NO x concentration, ppmvd
E lb NO x /Mbtu
%O 2 % oxygen in the flue gas.TABLE 9^
NO x emission standards for passenger cars and light duty trucks (g/mi)16,17New York California FederalPC LDTI^2 LDT2^3 PC LDTI^2 LDT2^3 PC LDTI^2 LDT2^3
5 yr/ 0.4 0.4 1.0 0.4 0.4 1.0 1.0 1.2 1.7
50,000 mi (0.7)^1 (0.7)^1
1993
10 yr/—————————
100,000 mi
5 yr/ 0.4 0.4 1.0 0.4 0.4 0.7–1.0 0.4–1.0 0.4–1.2 0.7–1.7
50,000 mi (0.7)^1 (0.7)^1
1994
10 yr/ — — — 0.6 0.6 0.9 0.6 0.6 0.97
100,000 mi
5 yr/ 0.4 0.4 0.7 0.4 0.4 0.7 0.4–1.0 0.4–1.2 0.7–1.7
50,000 mi
1995
10 yr/ — — — 0.6 0.6 0.9 0.6 0.6 0.97
100,000 mi1 The standard for in-use compliance for passenger cars and light duty trucks certifying to the 0.4 g/mi NO x standard shall be 0.55 g/mi NO x for 50,000
miles.
2 LDTI refers to light duty trucks from 0–3, 750 pounds loaded vehicle weight.
3 LDT2 refers to light duty trucks from 3,751–5750 pounds loaded vehicle weight, but less than 6,000 pounds gross vehicle weight.C014_002_r03.indd 753C014_002_r03.indd 753 11/18/2005 1:26:53 PM11/18/2005 1:26:53 PM