SN 16544.001
Test Number FA-3
AIRCO Alloys and Carbide
Niagara Falls, New York
by
T.E. Eggleston
RESOURCES RESEARCH. INC.
A SUBSIDIARY OF TRW INC.
WESTGATE PARK • 7600 COLSHIRE DRIVE • McLEAN. VIRGINIA 22101
Contract Number CPA 70-81
-------�
SN 16544.001
TEST NUMBER
AIRCO ALLOYS AND CARBIDE
NIAGARA FALLS, NEW YORK
by T.E. Eggleston
Revised
DECEMBER, 1971
Resources Research, Inc.
A Subsidiary of TRW Inc.
7600 Col shire Drive
McLean, Virginia 22101
Contract Number CPA 70-81
m
-------�
TABLE OF CONTENTS
Page
II. INTRODUCTION 2
III. SUMMARY OF RESULTS 4
IV. PROCESS DESCRIPTION 7
V. LOCATION OF SAMPLING POINTS 10
VI. PROCESS OPERATION 12
VII. SAMPLING PROCEDURES 13
VIII. CLEANUP AND ANALYTICAL PROCEDURES. ... 14
IX. DISCUSSION 15
A. Results 15
B. Operating Conditions 18
C. Test Conditions 19
X. APPENDIX 20
A. Complete Particulate Results with
Example Calculations
B. Complete Gaseous Results with
Example Calculations
C. Complete Operation Results
D. Field Data
E.I Sampling Procedures
E.2 Cleanup and Analytical Procedures
F. Laboratory Report
G. Test Logs
H. Related Reports
I. Project Participants and Titles
J. Particle Sizing Data and Results
K. Chemical Analysis of Emissions
-------�
LIST OF TABLES
Table No. Title Page
1 Summary of Results 5
LIST OF FIGURES
Figure No. Title Page
1 Block Diagram 3
2 Process Flow Diagram ^
3 Sample Point Locations 11
-------�
II. INTRODUCTION
Source emission tests are being performed on a series of electric
furnace installations, known as reactive metals or ferroalloys, for the
Office of Air Programs, Environmental Protection Agency. The tests include
grain loading measurements, particle size analyses, and chemical analyses
for a variety of furnace formulations and control devices. This report
covers the tests performed at the AIRCO Alloys and Carbide Plant, Niagara
Falls, New York, during the week of August 30, 1971.
Emissions for this particular plant were determined for a ferrochrome
silicon furnace (No.9). The furnace was provided with a hood with an in-
duced draft exhaust fan. This hood collected most of the dust and fumes,
except during the alloy "tapping" process. Sample point locations are
located in Figure 2. Further detailed diagrams and descriptions are
included in Section IV and V (Process Description and Location of Sampling
Points).
During this particular survey particulate matter was sampled using
the standard OAP train. Sulfur oxides were sampled using the Shell
Development method and integrated combustion gases were sampled in a gas
bag with analysis by standard Orsat. Particle size was measured in situ
with Brink Samplers. Samples for metals analysis were collected using the
standard EPA train.
-------�
( Atmosphere J
E lectrical
Power
Carbon
R e d u c i n g
Agents
Flux es, etc.
Elect
r o des
Electric Arc Furnace
FIGURE 1.
.BLOCK DIAGRAM
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III. SUMMARY OF RESULTS
Table I contains a summary of the results for particulate
sampling. They indicate an efficiency for the baghouse of approxi-
mately 96.5%. This figure is probably a little low due to the
particulate matter entering the baghouse exhaust with the induced
air. See the discussion for a more thorough explanation. The
average level of emission from the baghouse is approximately 30
pounds per hour. The inlet carries an average of approximately
1,827 pounds per hour.
The duct-work captures most of the fumes during the normal
operation of the furnace. During tapping, however, as much as 50%
of the fumes generated by tapping escape the duct-work.
Sulfur dioxide emissions from the baghouse averaged 8.8 ppm.
Particle sizing was carried out using BRINK cascade impactors.
The mass median diameter (HMD) for the baghouse exhaust was approxi-
mately 0.7 to 0.8 microns. The MMD for the furnace exhaust ranged
from 0.3 to 3.2 mdcrons during taps and between taps, respectively.
Complete results are contained in Appendix J«.
Metals analysis revealed a heterogeneous particulate material for
the furnace exhaust. Indications are that the material was a mixture
of oxides. The majority constituent of all the samples was silicon
dioxide. The only other large constituent was manganese. Complete
results are contained in Appendix J.
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SUMMARY OF RESULTS
BAGHOUSE OUTLET
Run Number
-. Date . . • '
.Stack Flow Rate - SCFH * dry
% Water Vapor - % Vol .
-^— jTCO^T~Vol % dry
% 02 - Vol % dry
% Excess air @ sampling point
S0? Emissions - ppm dry
. NO Emissions - ppm dry •
r\
Particulates
Probe, Cyclone, & Filter Catch
gr/SCF dry
gr/CF @ Stack Conditions
Ibs./hr.
Particulate from Impinger train
(% of total)
Total Catch
gr/SCF* dry
gr /CF (? Stack Conditions
Ibs./hr. -
r- - 1
ANE-1
ACE-1
8-31-71J 8-31-73
@383,OOOb383,OOC
1.00 0.22
0.5
20.6
5318
**
N/A
.0035
.0029
11.49
71
.0120
.0099
39.83
0.5
20.6
5318
-
-
.0042
.0035
13.79
69 '
.0135
.0112
44.31
,1
ASE-1 ANE-2
ACE- 2
8-31-71 9-1-71 9-1-71
1
@383,00(t@383,OOCi(3383,00(
! i
1.88
0.5
20.6
5318
-
- i
.0023
.0019
7.55
74
.0090
.0073
29.54
0.55 0.42
/
0.5
0.5 '
20.6 i20.6
5318
7
-
. .0038
.0031
12.47
.69
.0121
.0100
39.72
5318
-
-
.0028
.0023
9.19
«
71
. .0098
.0082
32.17
ASE-2
9-1-71
@ 383, 000
0.61
0.5
20.6
5318
-
-
.0020
.0017;
6.56
74
.0078
.0064
25.60
: J
@ Calculated from inlet volume and induced air
* 70'F ,29.92" Hg
** Not applicable for these specific samples
individual results.
See Appendix B for
-------�
SUMMARY OF RESULTS
BAGHOUSE OUTLET/INLET
Run Number
-. Date •..'"••
.Stack Flow Rate - SCFH * dry
% Water Vapor - % Vol .
-z— -JT'COp^Vol % dry
% 02 - Vol % dry
% Excess air @ sampling point
S02 Emissions - ppm dry
. NO Emissions - pp:;i dry •
A
Particulates
Probe, Cyclone, & Filter Catch
gr/SCF dry
gr/CF @ Stack Conditions
lbs./hr.
Particulate from impinger train
(% of total)
Total Catch
gr/SCF* dry
gr /CF @ Stack Conditions
]bs./hr. ••
t }
ANE-3 ACE-3
9-1-71 9-1-71
@383, 000(3383, 000
0.54 0.52
i
.5
20.6
5318
**
N/A
.0023
.0019
7.55
63
.0062
.0051
20.35
.5
20.6
5318
-
-
.0014
.0011
4.60
71
.0049
.0040
16.08
ASE-3
9-1-71
@383,OOC
0.15
•5
20.6
ABD-1
9-1-71
ABD-2
9-1-71
@174, 979@176, 09:
1.94 1 2.2
/
1.2 1.2
i
19 . 8 ' 19 . 8
•1
5318 j 1631 1631
-
-
ii
i
• .0016
.0013
5.25
70
.0054
.0045
17.72
• .5334
.3486
799.9
16.6
.6397
.4180
959.3
.-
~
.1189
.0785
173.2
*
70.3
.4001
.2641
603.8
ABD-3 ,
9-1-71
@181,08-
2.17 i
!
1.2
19.8
1631
-
~
.3983
.2587
594.4
32.7
.5917
.3842
918.2
@ Calcuated from inlet volume and induced air
** Not applicable for these specific samples:
individual results.
* 70°r ,29.92" My
See Appendix B for
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IV. PROCESS DESCRIPTION
The reactive metals are generally ferroalloys which are produced in
submerged arc electric furnaces. The facilities under consideration in
this report are open furnaces, with hooding, and emissions are ducted through
a baghouse after cooling. Figure 1 is a block diagram indicating
the inlet and outlet materials.
The electric arc is employed as a concentrated source of heat. Chrome
and other ores are added to the surface of the furnace through mechanized
equipment and chutes. Additional carbon in the form of coke, wood chips, etc.,
is an integral part of the furnace mix, along with specialized fluxes, etc. The
mix is added directly to the surface of the furnace through chutes and is then
spread over the surface with stoking machines.
The very high temperatures produced initiate a reaction in the bottom
of the furnaces and form a layer of metal which is tapped at appropriate
times. As the ore and carbonaceous materials settle to the bottom of the
furnace, the heat, in conjunction with a lack of oxygen, react with the
oxide ores to produce carbon monoxide which reacts further chemically, as
a reducing agent, in order to remove oxygen from the original ores and
thus produce the elemental metal. Escaping gases are burned at the surface
of the furnace in the so-called open units. In closed furnaces, these
gases may be burned in such a manner so as to salvage their heat value.
The furnace under test produced a ferrochrome silicon product.
Soderberg type electrodes are formed in place from a "paste" rather than
using prebaked carbon electrodes. Induced draft fans are employed to pull
fumes from the hooding into.the cooling system and baghouse. Any escaping
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fumes rise to louvers or monitors in the roof where they are discharged.
The furnaces are tapped at intervals of somewhat less than two
hours into ladles. The slag is removed from this ladle and disposed of
by various means. Molten product is poured into molds, after which it is
broken into usable sizes.
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VO
FURNACE
SAMPLING PORTS
EXHAUST
BAGHOUSE
FIGURE 2. PROCESS FLOW DIAGRAM
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V. LOCATION OF SAMPLING POINTS
Sample port locations were selected where most satisfactory
during a presurvey inspection trip, and approved by the GAP Project
Officer. On the collector inlet side four ports were selected on
the top side of the rectangular horizontal duoting, in the middle of
a long, straight section. On the outlet side three ports were selected
at the top of the baghouse. These locations were not ideal, but were
in the only available location. The location should have no signifi-
cant effect on the results due to the particle size and low concentration
of emissions from the baghouse. The inlet side required a framework to
suspend the sampling train over the ports, capable of moving the train
horizontally and vertically. Platforms were required on the outlet side
due to the slope of the roof. Sampling ports and platforms were provided
by the plant. Figure 2 (page 9) shows a simplified cross-section of the
system under test and indicates the relative location of sampling ports.
On the inlet side each of the cross-sections was divided for 5-position
sampling, giving a total of 20 equal-area sampling points. On the outlet
side three trains were used, one at each port.Only one point was sampled
at each port, six feet into the port. Figure 3 shows a sketch of the
location of the sample points.
The downstream sampling locations were agreed upon as acceptable,
although they did not meet the criteria as established by EPA/OAP. Further
discussion of this subject can be found in Section IX.
10
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N
N
• 5
• 4
• 3
N
•
ANE
C
•
S
•
6'
ACE
ASE
FURNACE EXHAUST DUCT
BAGHOUSE OUTLET
FIGURE 3- SAMPLE POINT LOCATION
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VI PROCESS OPERATION
Process operations were within normal parameters throughout
the testing period.
Actual operating data for the plant is contained in Appendix C.
The furnace was operating at 20,000 KW during the test periods.
The feed rate of materials was 25,000 Ib./hr. producing ferrochrome
silicon (36 parts chrome and 40 parts silicon).
The toal dust collected from the baghouse storage hopper in
a 47-3/4 hour period was 44,620 pounds. This indicates an emission
rate of approximately 935 Ib./hr.
12
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VII. SAMPLING PROCEDURES
All test procedures were discussed with the Project Officer in
advance. All procedures were essentially the same as those being issued
by the Environmental Protection Agency for source sampling.
Preliminary velocity and temperature readings were obtained in
order to select nozzle sizes for isokinetic sampling. Particulate
sampling was .conducted using the OAP train as described in Appendix E-l.
Gas sampling was also conducted in accordance with the proposed
EPA standard source ttsting methods. Sulfur dioxide was sampled with
midget impingers using isopropyl alcohol and hydrogen peroxide solutions.
Combustion gases were sampled in plastic bags for immediate analysis with
an Orsat analyzer.
Particle sizing was carried out using Brink cascade impactor collec-
tors.
Sampling for metals analysis was conducted using the OAP train with
glass probe, without the cyclone collector. Only the material collected
on the filter was saved for analysis.
13
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VIII. CLEANUP AND ANALYTICAL PROCEDURES
Clean-up of the EPA particulate train was conducted in accordance
with the procedures as outlined in the standard EPA source testing
methods. Basically the clean-up is accomplished using acetone and
water rinsing, placing the various portions of the samples in separate
containers, and then drying the samples, and extracting organic material
from the water. These procedures are outlined in detail in Appendix E-2.
Sulfur dioxide was analyzed for using the Modified Shell Development
Method.
Combustion gases were analyzed on site by Orsat measurement using
a Burrell Industrial Gas Analyzer.
Particle size determination was carried out in the plant laboratory
using a recently calibrated Mettler scale.
Metals analysis is accomplished using various methods, including
electron beam microanalysis and atomic absorption.
See Appendix E-2 for further details.
14
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IX DISCUSSION
A. Results
Continued problems were encountered with the filter of the EPA
smapling train plugging during sampling. (See related report FA-1
for previous problems). After experiencing rapid plugging of the filters
on sample ABD-1, possible solutions were discussed with the EPA represent-
atives. The decision was made to place the filter after the first three
impingers. Therefore, the data resulting from the particulate split
is not reliable for samples ABD-2 and ABD-3. It is, however, represent-
ative of total emissions. This fix improved the situation and only
one other related problem was encountered at this location. During
sample ABD-2 one impinger orifice plugged. The train was shutdown and
the tip was carefully cleared before continuing the sample.
The outlet samples taken on the baghouse were run non-isokinetically
at a high sampling rate. The reason for this was to allow a larger sample
volume to be collected. Due to the high efficiency of the baghouse,
it was agreed that the concentration of particulate matter would be
very low and that the particle sizes would be very small. This would
necessitate a large sample volume and would allow representative sampling
without iso-kinetic flow. The data collected supported these conclusions.
Therefore, the data is considered representative and reliable. Each
sample was calculated to give an emission rate in pounds per hour
based on the entire air flow through the baghouse.
The computed baghouse efficiency of approximately 96.5% is not
-------�
necessarily correct. Actual efficiency is probably in excess of
98%. Induced air is over half of the volume of air leaving the
baghouse. The air being induced at the bottom of the baghouse is
heavily laden with dust from the surrounding area, including the
emissions from a near-by-plant. Although the sample locations sampled
the air leaving the bags proper, some induced air was probably sampled
also, causing the sample not to be completely representative of the
emissions from the bags. A high volume air sample taken (not by RRI)
near the bottom, but not in, the baghouse during the sampling program
supports the belief that a significant amount of what is emitted from
the baghouse exhaust is introduced by induced air. Personal experience
with baghouse operations and past history support the conclusion that
the baghouse is probably a little more efficient than the calculated
value.
The induced air was measured using a rotary vane anemometer to
measure the air flow around the bag compartments. Three of the total
of twelve compartments were measured. Multiple points were measured
in each compartment and they indicated a very uniform flow rate from
point to point and compartment to compartment. The open area around
each compartment was estimated by first measuring the area, then an
80% open area in the grating surface was estimated, using this
fraction as effective area. The volume estimated from this information
was then added to the average volume measured on the baghouse inlet
duct. No correction was made for possible leakage in the system prior
to the baghouse.
16
-------�
The samples taken for combustion gas analysis by Orsat showed
very low CC>2 and high 02 concentrations. The calculations indicate
that perhaps the Orsat measurement of combusion gases and calculation
of "excess air" is not completely representative for this particular
process.
The filterable particulate at the outlet of the baghouse ranged
from 26% to 37%. Thus the majority of the emissions from the bags
are either very fine particulate or "condensible" fumes. This further
supports the decision to use non-isokinetic sampling. The only
sampling taken on the furnace exhaust with the sampling train in a
normal configuration was ABD-1. This sample indicates that this gas
carries an approximate 15-85 split between "condensible" and filterable
material. Previous tests (FA-1 and FA-2) have indicated the "condensible"
portion of the fumes to be less than 5% of the total catch. No feasible
explanation can be made as to why this apparent discrepancy exists.
The particle size measurements taken indicate a very small mass
median diameter (HMD) at the baghouse outlet. Very long samples were
required at this location in order to insure adequate sample deposition
on the plates for weighing. Sampling ranged from 2 to 4 hours. The
furnace exhaust sampling presented the opposite problem. Sampling
time had to be reduced to 5 minutes to avoid overloading the impactor
plates. The MMD at this location varied widely between samples (indicative
of the nature of the process) and was distinctly larger during non-
tapping periods. This would indicate that the tapping process released
17
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a finer particulate or fumes than normal non-tapping operation.
Chemical analysis of the particulate emissions revealed that the
emissions were largely oxides and primarily silicon dioxide. The
results present no new or unexpected information.
B. Operating Conditions
The operation of furnace # 9 is nonuniform, involving a series
of feeding, spreading and tapping operations. This would explain at
least part of the variation in emission data gathered.
In conjunction with the tests performed by Resources Research,
Airco Alloys and Carbide measured the amount of collected dust from
the baghouse during a period of almost two days. The material collected
came to approximately 935 Ib./hr. This correlates closely with the
measured amount at the furnace exhaust duct, and very closely with
samples ABD-1 and ABD-3 (959.3 Ib./hr and 918.2 Ib./hr.).
The hood and duct work used to collect the furnace emissions
was very efficient during between tap operation, collecting approximately
95% of the emissions. The hood and duct work for the tapping area
was far less efficient and collected only about half of the tapping
emissions.
18
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C. Sampling and Analytical Procedures
All sampling methods, and analytical procedures where appropriate,
were essentially the same as those methods being issued by the
Environmental Protection Agency for source sampling. Any deviations
are indicated at the appropriate location in this report and were
carried out with permission of the EPA project officer.
The sample ports on the furnace exhaust duct presented a minor
sampling problem. Their location required vertical traverses at a
slight angle from the true vertical. Thus the sample box and probe
had to be held in place at all times while being suspended by a block
and tackle arrangement. The ports were in the middle of a long
straight duct, at least 10 pipe diameters from any bends or obstruction
up or downstream.
19
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X APPENDICES
20
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APPENDIX A
COMPLETE PARTICULATE RESULTS
WITH EXAMPLE CALCULATIONS
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SUMMARY OF RESULTS
BAGHOUSE OUTLET
Run Number
;. Date • . . " •
' .Stack Flow Rate - SCFM * dry
% Water Vapor - % Vol .
-^"iTCO^Vol % dry
% 02 - Vol % dry '
% Excess' air @ sampling point
S0? Emissions - ppm dry
. -NO Emissions - ppm dry •
A
Particulates
Probe, Cyclone, & Filter Catch
*
gr/SCF dry
gr/CF @ Stack Conditions
Ibs./hr.
Particulate from Impinger train
(% of total)
Total Catch
gr/SCF* dry
gr /CF (? Stack Conditions
Ibs./hr. .
ANE-l
ACE-1
8-31-71J 8-31-7]
@383,000
1.00
0.5
20.6
5318
**
N/A
.0035
.0029
11.49
71
.0120
.0099
39.83
@383,00(
0.22
0.5
20.6
5318
-
-
•
.0042
.0035
13.79
69 '
.0135
.0112
44.31
ASE-1
8-31-7!
@383,00(
1.88
0.5
20.6
5318
-
-
.0023
.0019
7.55
74
.0090
.0073
29.54
ANE-2
9-1-71
ACE- 2
9-1-71
@383,000.@383,00(
0.55 0.42
V
0.5
20.6
5318
-
-
•
. .0038
.0031
12.47
.69
.0121
.0100
39.72
0.5 '
20.6
5318
-• '
-
.0028
.0023
9.19
•
71
. .0098
.0082
32.17
ASE-2
9-1-71
(§383,00
0.61
0.5
20.6
5318
-
-
i
.0020
.0017
6.56 i
i
74
.0078
.0064
25.60
@ Calculated from inlet volume and induced air
* 70°F,29.92" He,
** Not applicable for these specific samples;
individual result.-;.
See Appendix B for
A-l
-------�
SUMMARY OF RESULTS
BAGHOUSE OUTLET/INLET
Run Numhor
.. Date • . . • '
.Stack Flow Rate - SCFM-* dry
% Water Vapor - % Vol .
-i— JT"CO^T"Vol % dry
X 02 - Vol % dry
% Excess air @ sampling point
S0« Emissions - ppm dry
. --NO Emissions - ppm dry •
A
Particulates
Probe, Cyclone, & Filter Catch
*
gr/SCF dry
gr/CF @ Stack Conditions
Ibs./hr.
Particulate from impinger train
'(% of total)
Total Catch
gr/SCF* dry
gr /CF (? Stack Conditions
Ibs./nr. -.
ANE-3
9-1-71
ACE- 3
9-1-71
5383, OOOP383,000
0.54
.5
20.6
5318
**
N/A
.0023
.0019
7.55
63
• f
.0062
.0051
20.35
0.52
.5
20.6
5318
-
-
.0014
.0011
4.60
71
.0049
.0040
16.08
ASE-3
9-1-71
@383,OOC
0.15
.5
20.6
5318
-
-
• .Obl6
.0013
5.25
70
.0054
.0 •;••«
17.72
ABD-1
9-1-71
ABD-2
9-1-71
(§174,979^176,093
1.94
2.2
1?2 1.2
19.8
1631
-
—
.- .5334
.3486
799.9
16.6
.6397
.4180
959.3
19.8
1631
.-
—
.1189
.0785
173.2
«
70.3
.4001
.2641
603.8
ABD-3
9-1-71
@181,083
2.17
.1.2
19.8
1631
-
—
t
.3983
<|
.2587
594.4
32.7 !
• i
.5917
.3842
918.2
@ Calcuated from inlet volume and induced air
** Not applicable for these specific samples:
individual results.
* 70eF,29.92" Hcj
See Appendix B for
A-2
-------�
REPORT NO.
PAGE
OF
PAGES
SOURCE TESTING CALCULATION FORMS
Test. No.
No. Runs
6
Name of Firm AIRCQ
Location of Plant
*.
NIAGARA FALLS. N.-Y.
Type" of Plant REACTIVE METAL • . •' • --
Control Equipment
Sampling Point Local
Pollutants Sampled
Time of Parti cul ate
Run No. ANE-1
ACE-1 .
Run, No. ACIT i
Run No. ACE.?
Run No..-. ASE-2
BAG FILTERS "' : ' - - - -
Ll'OnS -BAGHOUSE EXHAUST
t
PARTICULATE . ' .
Test: '
Date s-31-71 Begin 17:19
,, ^ 8-31-71 • „ . 17:23
Date e-31-71 Begin 17,9?
• 9-1-71 09:02
Date 0.^71 Begin, no- is
Date 9-1-71 • Beein 09:10
• •
End 19:19
19:23
tnd 19:22
13:10
End 13:02
End . 12:49
PARTICULATE EMISSION DATA
Run No. . •
P. barometric pressure, "Hg Absolute
b
p orifice pressure drop, "FLO
i" *•
V volume of dry gas sampled @ meter
m conditions, ft. 3
T Average Gas Meter Temperature, °F
V Volume of Dry Gas Sampled @ Standard
std. Conditions, ft. 3
V Total ILO collected, ml., Impingers
H & Silical Gel.
V Volume of Water Vapor Collected
wgas ft. 3 0 Standard Conditions*
ANE-l! ^r.F.-1
.29_.8 • 29.8
!
. 2.0. , 2..Q_
i
92.54J 93.42
ASE-1
.JJ9^8 .
..2.O..
95.09
! ;
92 114 j 112
(
88.72, 86.13; 87.97
I
18.9 4.0
- - 1 J
. -|- -J
.90 j .19
35.7
1.69
ANE-2
29_J5
...JLJ3...
118. 3<
116
109. i:
13.7
0.6
A"7-?,
.2^1_
.4.JQ..
129.22
-^£E=2
_29,8,.
4J)
136.9-
t
122 j 112
118.27
11.4
0.5
.
l
127. 5^
16.5
\
0.78 j
1 * 70°F, 29.92" Hg
A-3
-------�
PARTICULATE EMISSION DATA (cont'cl)
Run No. . . . .
%M - % Moisture in the stack gas by volume
M. - Mole fraction of dry gas
% co2 . •
% 07 : •
% N2 • ' "
M W d - Molecular weight. of dry stack gas
M W - Molecular weight of stack gas
4.Ps - Velocity Head of stack gas, In. HO
T - - Stack Temperature,°F
[^PSX(TS+460J
P - Stack Pressure, "Hg. Absolute
V - Stack Velocity 0 stack conditions, fpni
s
A - Stack Area, in.
Q - Stack Gas Volume @ * *
Standard Conditions, SCFM
Tt - Net Time of Test, min.
D - Sampling Nozzle Diameter, in.
%l - Percent isokinetic
m,: - Particulate - probe, cyclone
and filter, mg.
m - Particulate - total, mg.
C - Particulate - probe, cyclone,
an and filter, gr/SCF
C - Particulate - total, gr/SCF
ao
i C - Particulate - probe, cyclone, & filter
j gr/cf P stack conditions
n 1
ANE-1 { ACE-i ASE-]
!
1.00 j .22
0.99
0.5
20.6
78.9 ,
28 Q
2R.R
175
-
1.00
0.5
20.6
78.9
28.9.
2R.Q
175
-
29.8 29.8
-
383,
000
120
.50
-
20.4
69.5
.0035
.0120
(.0029
-
-
383,
000
120
.50
•
23.4
75.3
.0042
.0135
.0035
1.88.
ANE-2 ACE-2
1 i
; l
0.55 ! 0.42
• i 1
0.98 0.99 | 1.0
0.5
20.6
.78.9
28^9
2R.7
175
j
0.5 i 0.5 i
20.6 J20.6
78.9 ;78.9 ,
u-28^9
2R.Q
172
>
28.9 '
2R.q_
172
29.8 29.8 , 29.8
!
-
383,
000
120
\ ~
i
383, 383,
000 000 ,
ASE-2
.61
.99
0.5
20.6
78.9
28.9
2&J&.
172
-
29.8
~
383,
. 000
1
138 ! 120 ,120
'( " '
.50; .50 .50 .50
-
13.0
51.3
.002:
.009(
.001?
-
i ' '
26.6
85.6
i .0038
.0121
.0031
i
21.8
71.2
.0028
.0098
.0023
_ .
16.9
64.5
.0020
.0078
.0017
* Calculated from inlet volume plus induced air
A-4
-------�
PARTICIPATE' EMISSION DATA (ccnt'ci)
Run No. •
C - Parti culete, total, gr/cf
ej @ stack cond.
C - Particulate, probe, cyclone,
aw and filter, Ib/hr.
C - Particulate - total, Ib/hr.
ax
% EA - % Excess air @
i>uiup i i iiy [j j i ii L. ,,.,...
ANE-1
.0099
LI. 49
J9.83
5318
ACE-1
.Oil:
13.79
44.31
5318
ASE-1
.0072
7.55
29.54
5318
'
ANE-2
.0100
12.47
39.72
5318
•
ACE- 2
.0082
9.19
32.17
5318
ASE-2
.0064
5.56
25.60
5318
70°F. 29.92" Hg.
A-5
-------�
REPORT NO.
PAGE
OF
PAGES
SOURCE TESTING CALCULATION FORMS
Test/No.
No.
Runs 6
" " * .
Name of Fi nn AIRCO
Location of Plant
Type' of Plant
Control Equipment
Sampling Point Local
Pollutants Sampled
Time of Parti cul ate
ANE-3
Run No . ACE-3
Run No.jisp-3
ABD-1
Run No. ABD-Z
Run No.^Rp-1.
'
NIAGARA FALLS. N.Y.
REACTIVE METAL •
BAG FILTERS " . - - - -
tl'OnS HAmiOTTRF. FYHATlST/FUHNAfF, EXHAUST
t
PARTICULATE;
Test: .'. .- '•• V " •
Date?"i"71 Beq1n it 1 32
Datctgii_7i Begin 14:30
.8-31-71 17:17
Date 9-1-71 Begin 09:10
Date 9-1-71 ' Begin lA-'AO
'' PARTICULATE EMISSION DATA
- - .
. .
c j 17:34
End 17:12
End 17:30
18:57
End 10:50
End -i A . ?n
Run No.
P. barometric pressure, "Hg Absolute
b
p orifice pressure drop, "H^O
it[ <-
V volume of dry gas sampled @ meter
conditions, ft. 3
T Average Gas Meter Temperature, °F
V Volume of Dry Gas Sampled P Standard
mstd. Conditions, ft. 3
V Total H-O collected, ml., Impingers
w & Silica! Gel.
V Volume of U'ater Vapor Collected
wgas ft. 3 (3 Standard Conditions*
ANE-3
29.8
"* 3
184.0
131
165.3
18.9
0.9
ACE-3
29.8
-4.S
214.06
118
L91.34
20.4
0.97
-ASJL-^L
29.8
4 3.
216.26
l^n
195. 21
7.3
0.3
ABD-L
29.8
86
52.75
QT
. 50.4^
21.7
1.0
ABD-2
29.8
fl£
51.35
as
...
49.86
•
23.7
1.1
-ABD-3
29.8
Q 9
52.01
1
100
.
49. ;5
\
23.0
1
1.09 j
1 * 70°F, 29.92" Hg
A-6
-------�
PARTICULATE EMISSION DATA (cont'd)
R-jn No. .•"•"•.""
%M - % Moisture in the stack gas by volume
Md - Mole fraction of dry gas
% co2 . • .
% o2 .. , : . •
% N2 . . . . v
M W . - Molecular weight. of dry stack gas
M W - Molecular weight of stack gas
APs - Velocity Head of stack gas, In. HO
T • - Stack Temperature, F
[;&PSX(TS+466T
PS - Stack Pressure, "Hg. Absolute
Vs - Stack Velocity @ stack conditions, fpni
2
A - Stack Area, in.
Q - Stack Gas Volume @ *
Standard Conditions, SCFM
T. - Net Time of Test, min.
Dp - Sampling Nozzle Diameter, in.
%l - Percent^ isokinetic
nu - Particulate - probe, cyclone
and filter, mg.
m - Particulate - total, mg.
C - Particulate - probe, cyclone,
an and filter, gr/SCF
C - Particulate - total, gr/SCF
ao
L: C - Particulate - probe, cyclone, & filter
gr/cf P stack conditions
ANE-3 |
0.54
1.0
0.5
20.6
78.9
'
28.9
28.9
-
178
;
i
29.8 I
<
383,
000
180
.500
-
24.7
i6.1
.0023
.0062
| .0019
t
ACE- 3
0.52
0.99
0.5
20.6
78.9
28.9
28.8
-
178
-
29.8
-
-
383,
000
180
.500
i
-
17.6
60.9
.0014
.0049
.0011
i _. .
ASE-3.
0.15
1.0
0.5
20.6
78.9
28.9
28.9
-
178
-
29.8
-
-
383,
000
180
.500
-
20.6
68.1
.0016
.0054
.0013
ABD-1
1.94
1.0 j
1.2
19.8
79.0
/
29.0
28.8
.89
331
26.5
m - - 4
29.8
3935
9792
174,
979
100
:
.1875
107.1
1,746.
5
2,094.
3
.5334
.6397
.3486
ABD-2
2.2
0.98
1.2
19.8
79.0
29.0
28.8
.89
323
26.4
29.8
3920
9792
176,
093
100
.1875
120.8
385.0
1,297.
2
.1189
.4001
.0785
i
ABD-3
2.17
0.98
1.2
19.8
79.0
29.0
28.8
L
.96
336
27.6
29.8
4098
9792
181,
083
100
.1875
102.3
1,271
2
1,888
6
'.3983
1
.5917
.2587
A-7
-------�
PARTICIPATE'EMISSION DATA (cont'ci)
Run Ito. • ' '
C - Participate, total, gr/cf
@ stack cond.
C - Particulate, probe, cyclone,
aw and filter, Ib/hr.
C_ - Particulate - total, Ib/hr.
ax
% EA - 2 Excess air (3
Suiupi intj p j i u w •
ANE-3
.0051
7.55
20.35
5318
ACE-:
.0040
4.60
16.08
5318
. .
ASE-2
.0045
5.25
17.72
5318
'
ABD-1
.4180
799.9
959.3
1631
ABD-2
.2641
179.4
603.8
1631
ABD-3
.3842
618.1
918.2
1631
70°F. 29.92" Hg.
A-8
-------�
SAMPLE PARTICULATE CALCULATIONS
ABD-1
1. Volume of dry gas sampled at standard conditions - 70°F, 29.92"
Hg, ft3.
17'7XVm
Vmstd
17.7 X 52.75 (29.8 + 0<86
13.6
(93 + 460)
50.42
2. Volume of water vapor at 70°F and 29.92" Hg, Ft.3
Vw = 0.0474 X Vw = ft.3
gas
0.0474 X 21.7 »
1.0
3. % moisture in stack gas
100 X V
gas = %
v TV
mstd wgas
100 X 1.0
50.42 + 1.0
1.94
A-9
-------�
4. Mole fraction of dry gas
M _ TOO - %M
Md Too—
100 - 1.94
100
0.98
5. Average molecular weight of dry stack gas
M W d = (%C02 X ^-Q-) + (%02 X y^-) + (%N2 X
(1.2 X ^g- ) + (19.8 X -^j ) + (79.0 X
28.98
6. Molecular weight of stack gas
M W - M W d X Md + 18 (1 - Md)
28.98 X 0.98 + 18 (1 - 0.98) =
28.76
7. Stack velocity @ stack conditions, fprn
1/2
Vs = 4350 Xv/AP^X (T$ + 460) | 5—TTHT I = fPm
4350 X >/.89 X (331 + 460) (^ 1
29.8 X 28.76
u.~. ^J
= 1/2
129.8 X 28.76J
3935
A-10
-------�
8. Stack gas volume @ standard conditions, SCFM
0.123 XV XA X M . X P
n - s s d s _ SCFM
ys (Ts + 460) iLm
. 0.23 X 3935 X 9792 X 0.98 X 29.8 =
(331 + 460)
174,979
9. Percent isokinetic
1032 X (T + 460) X V
X Tt X Ps X Md X (Dn)2
1032 X (331 + 460) X 52.75
3935 X 100 X 29.8 X 0.98 X 0.035
107.1
10. Participate - probe, cyclone, and filter, gr/SCF
Mf
C = 0.0154 X u' T = gr/scf
m
mstd
0.0154 X 1746'5
50.42
0.5334
11. Particulate total, gr/SCF
M
Cfl0 = 0.0154 X y—— = gr/SCF
mstd
- 0.0154 X 2094'3
50.42
0.6397
A-ll
-------�
12. Participate - probe, cyclone and filter,
gr/CF at stack conditions
17.7 X C X P X M ,
_ an s d
(Ts + 460)
17.7 X 0.5334 X 29.8 X 0.98
(331 + 460)
0.3486
13. Participate - total, gr/CF @ stack conditions
17.7 X Can X Pc X M ,
r 30 S d
C
au + 460
A
17.7 X 0.6397 X 29.8 X 0.98
(331 + 460)
0.4180
14. Participate - probe, cyclone filter filter, Ib/hr,
Caw = 0.00857 X Can X Qs = Ib/hr.
0.00857 X 0.5334 X 174979
799.9
15. Participate - total, Ib/hr.
C = 0.00857 X C X Q = Ib/hr.
ax ao s
= 0.00857 X 0.6397 X 174979 =
959.3
A-12
-------�
16. % excess air at sampling point
100 X % 09
v rfl - . . -f .
* tH "(0.266 X % N2)-« 0
100 X 19.8
= (0.266 X 79.0)- 19.8
1631
A-13
-------�
BAGHOUSE EXHAUST VOLUME (Q )
s
DETERMINATION
AVERAGE Q . INLET:
S
NUMBER OF BAG COMPARTMENTS:
178,000 cfm
12
AREA AROUND EACH COMPARTMENT (including grating) 88 ft
AREA OPEN AROUND BAG COMPARTMENTS: 853 ft2
(estimated 80% open area)
VELOCITY (avg.) AROUND BAG COMPARTMENTS: 240.1 fpm
(3 compartments measured and averaged)
Qs INDUCED: 205,000cfm
Qs TOTAL: . 383,000cfm
EFFECTIVE AREA = 88ft2 X .80 X 12 = 853 ft2
AVG. VELOCITY = 237. 4 + 239.1+ 243.8 = ^ fpm
Qs INDUCED = 240.1 ft/min. X 853 f t2 = 204,805 cfm = app. 205,000 cfm
Q TOTAL = 205,000 cfm + 178,000 cfm = 383,000 cfm
S
A-14
-------�
APPENDIX B
COMPLETE GASEOUS RESULTS WITH EXAMPLE CALCULATIONS
-------�
.MTCCTAM
Run No. . '
BAGHOUSE EXHAUST
Date
mg S02 , • _
T - Average Gas Meter Temperature, °F
m
P. - _Barometric -Pressure, "Hg abs.
V - Volume of dry gas sampled @ meter
m conditions, ft.-*
• ppm SOp
ANE-1
9/2/71
2."5
84
29.8
3.96
9.Q
ACE-1
9/2/71
2.4 "
84
29.8
3.82
S.t
ASE-1
9/1/71
10.8
107
29.8
17.78
8.5
*
0.7332 X mg S09 X (T + 460)
._. a c. . m
- ppm S02 =
X
NOT USED ON .AGE-1, ANE-1
•" DUE TO VACUUM'ON METER
me SO
•2- - 9 s •
VSTD X 13.1 = ppm S00 = ^ v
2 3,64. X
VSTD- = Vm .(
530
J (
Pb - Pm )
= 9.0
= -3.96 (
530
84+460
29.8 - 1.6
29.92
B-l
-------�
DETERMINATION OF SO,, EMISSIONS*
ACE & ANE-1
Date Time Sample Vstd-Metered Gas Vol. **
Sample Location Sampled Sampled Number milligrams (dry, STD) milligrams/cu ft factor ppm
Baghouse Exhaust 9/2/71 1239-1339 ANE-1 2.5 3.64 .69 13.1 9.0
9/2/71 1032-1208 ACE-1 2.4 3.52 .68 13.1 8.9
* This special format was used instead of the GAP forms for samples
ANE-1 & ACE1 because the meter was kept under vacuum, that is before
the pump.
** From page 173, Source Testing Manual, County of Los Angeles, California.
bd
I
NJ
-------�
Part 10, p. 7 of 8
OR5AT FIELD DATA
Location
Date_
Time
Operator
OUTLET
9/2/71
A.M.
BLESSING
Comments:
Test
Run
1
2
3
Avg.
(co2)
Reading 1
0.5 .
0.5
0.5
0.5
(o2)
Reading 2
21.2
21.4
20.8
21.13
•
(CO)
Reading 3
0
0
0
0 .
NCl'VI'-rtl (12/07)
B-3
-------�
Part 10, p. 7 of 8
ORSAT FIELD DATA
Location
Time
Operator
INLET
9/1/71
P.M.
Blessing
Comments:
Test
Run
1
2
3
Avg.
(co2)
Reading 1
1-2.
1.2
1.2
1.2
(o2)
Reading 2
21.4
21.4
.20.2
21.0
'
(CO)
Reading 3
0
0
0
0
NC'\P-31 (12/07)
B-4
-------�
APPENDIX C
COMPLETE OPERATION RESULTS
-------�
i J -M
.--•m •
TifST
7PM
* :,
I'T-
! •*:
*'^
.JBpM.
5M.J
;Haio»32i3
L '^- '<•'
i^CM
Tferj
T^
T
No.
FufcMACc LOADS
A/A.CO
C-l
-------�
...
C-2
-------�
Temperature Recorder
Li&t
Location
re- 1
1C-Z
TC-3
rc-4
TC-3
TC--S
TC-7
TC-&
TC '3
7C-IO
TC II
re 12
TC-14
TC-/S
TC-lfc
TC-17 .
TC 13
TC I*
TC SS
TC-21
TC-2e
TC-23.
TC-24
-tenip. bji^wecn Uest
t
temp, betv/eeo East -4 KJor+h electrode^
doghouse tfirnp.
doghouse temp.
East doghouse
Cenfei- of Hoed t
-------�
o
ESTEBXINE .SWOTS
INDIANAPOLIS. (NO.. U.S.A.
-------�
ESTEXLXHE J&BSOTS
INDIANAPOLIS. IND-, U.SJt.
INDIANAPOLIS. IND.. U.S.A.
-------�
NAPOLIS. IND.. U.S.A.
n
ON
-------�
ESTER1DTE'
INDIANAPOLIS. IND.. U.S.A.
n
-------�
APPENDIX D
Field Data
-------�
Run No. ANE-1
Location Baghouse.North Exhaust
Date
.8-31-71
PARTICULATE FIELD DATA
IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F 770 _ a?°
Bar. Press. "Hg 29.8
Assumed Moisture
Operator Eggieston
Sample Box No. 2
Meter Box No. 51047
Heater Box Setting, °F 250
Probe Tip D1a., In.
Probe Length
1/2
Probe Heater Setting
Point
fi«
Clock
Time
1 7;1Q
17:25
17:37
17:45
17:55
18:05
18:20
18:30
LS:40
18:50
18:60
13:10
i a. i a
Dry Gas
Meter, CF
Q1 S 16
919.6
928.1
9-U.fi
942.0
949.6
-.
^
^
_
-.
^
innv Q
P1tot
1n. H20
AP
Orifice
1n H,
Desired *
AH
0
Actual
2
2
2
2
2
2
it
M
M
it
it
ii
ii
Dry Gas Temp.
°F
Inlet
72
74
82
Q1
98
108
1 7n
°6
110
i ns
107
105
Outlet
72
72
71
7s
ftR
Q4
07
90
92
Q?
on
9s
Pump
Vacuum
In. Hg
Gauge
7
7
7
7
7
7
7
7
7
7
7
^
7
Box
Temp.
CF
?so
250
250
2 if)
7«;n
9«ip
ii
ii
ii
ii
ii
•f
it
Impinger
Temp
°F
«s
90
85
85
on
on
Q-^
QR
95
on
fin
flO
Stack
Press
1n. Hg
9Q Rn
II
II
II
II
II
II
II
II
II
II
II
Stack
Tcrap
°F
170
_
1 S\
^
—
«•
Comments:
NCAP-37 (12/67)
o
-------�
PARTICULATE FIELD DATA
Run No. ACE - l
Locati OnBaghouse Center Exhaust
Date 8-31-71
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F
75l
Bar. Press. "Hg 29.8
Assumed Moisture % 2-°
Operator Blessing
Sample Box No.
Meter Box No.
4 •
. Heater Box Setting, °F 250
Probe Tip Dla., In.
Probe Length
0.50
Probe Heater Setting
Point
£•
1
Clock
Time
17:23
17:43
17:53
18:03
18:13
1ft:23
18; 33
18:43
18:53
19:03
19?1 3
IQ'7^
Dry Gas
Meter, CF
963. 3rt
979.20
987.38
_
_
—
-
_
in^A 77
PI tot
In. H20
AP
Orifice AH
1n HoO
Desired tt
Actual
7 ft
2.0
7 n
n
ii
ii
ii
ii
ii
ii
ii
ii
Dry Gas Temp.
°F
Inlet
91
106
11A
17A
173
130
130
132
132
120
127
130
Outlet
91
90
04
IftA
1 1 S
110
112
116
116
112
112
112
Pump
Vacuum
In. Hg
Gauge
7.7
7.5
7 S
7 <;
7 «;
7 e
7 1
7 c
7 5
7.S
7 5
7 c
Box
Temp.
°F
2SO
250
250
n
it
it
ii
n
ii
n
n
n
Implnger
Temp
°F
70
75
75
75
78
7«
78
7O
72
7/1
Stack
Press
1n. Hg
7Q ft
_
ii
ii
ii
n
IP
ii
ti
it
ii
Stack
Temp
°F
i 7n
n
ii
ii
ii
n
n
• I
ti
ti
ti
it
Comments:
NCAP-37 (12/67)
-------�
Run No.
PARTICIPATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS
Location ASF.-I
Date
- South Read and record at the start of
each test point.
Ambient Temp °F 86
Bar. Press. "Hg 29.8
\
>3-3i-7i
Assumed Moisture % 2%
Operator Blessing
Sample Box NOH
Meter Box No.
H
Heater Box Setting, °F 250
Probe Tip Dia., In._
Probe Length
50_
6.5
Probe Heater Setting 250
Point
ti\
1
Clock
Time
17 t22
17 '42
17-S9
iR.n?
1R- J9
1R?79
18:32
18:42
18't52
1° '0?
19:12
10-77
Dry Gas
Meter, CF
ftl5 Q1
931 "*0
ft •*
170
160
160
xulr —
Comments:
NCAP-37 (12/67)
o
u>
-------�
PARTICULATE FIELD DATA
Run No. AttTr-9
Location Bag Exh
Date
9-1-71
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F 80
Bar. Press. "Hg 29.8
\
Assumed Moisture % 2
Operator
McReynolds
Sample Box No.
Meter Box No.
Heater Box Setting, °F 170
Probe Tip Dia.t In. 5
Probe Length 6
Probe Heater Setting 7p_
Point
6"
*
i
I
1
Clock
Time
09:02
11-11
Hi 20
11 ;30
11:40
lli5Q
12 lOO
1 ° 1 10
1? • 'n
12i3Q
lli'iO
1 2 1 50
13'n9
13-10
Dry Gas
Meter, CF
08.08
17 51
^7_AR
_
196 AQ
Pi tot
in. HgO
AP
_
Orifice AH
in H00
Desired '
_
Actual
•} 9
0 1
3-°
3 n
•^.n
"\ 0
o n
3 n
3 0
9 Q
9 Q
2 Q
2 9
2.9
Dry Gas Temp.
°F
Inlet
8R
10°
Un
197
1 ™
128
1 *^0
IV}
13/,
1 ^9
1^9
i -*n
136
138
Outlet
84
TOO
11Q
inA
TOR
ino
110
112
1 19
112
119
112
112
Pump
Vacuum
In. Hg
Gauge
1° 0
19 °
2.0
1Q ^
1Q S
10 S
1Q.S
19 5
1Q 2
19.1
1Q 1
19.1
19.1
Box
Temp.
°F
170
1 7fi
170
it
n
n
n
n
n
n
ii
n
n
n
Impinger
Temp
°F
75
7 S
75
RH
7=1
7-;
?5
7^
70
70
75
75
75
Stack
Press
in. Hg
OO Q
II
II
II
II
II
II
II
II
II
II
II
It
II
Stack
Tc:rip
°r
it
H
ii
M
ii
M
H
ii
H
M
II
It
Comments: Off @ 9:21 power failure
NCAP-37 (12/67)
-------�
Run No. ACE-2
Location
Date
PARTICIPATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS , Ambient Temp °F
Bag Exh
Read and record at the start of
each test point.
Bar. Press. "Hg 29.8
9-1-71
Assumed Moisture
2%
Operator McReynolds
Sample Box No.
Meter Box No.
H
Heater Box Setting, °F 25°
Probe Tip Dia., In. 5
Probe Length 6
Probe Heater Setting 65
Point
*f
A
i
1
Clock
Time
DQ;1S
11)08
11;18
11:28
1 !• 3R
11:48
11* "^8
12;OR
19- IS
12:28
121 la
12 • '\ 8
l??5«
13i02
Dry Gas
Meter, CF
ns? 71
_
_
_
_
_
1 OC. 00
Pi tot
in. HgO
AP
Orifice AH
in HoO
Desired *
1
Actual
/I Q
II
II
II
II
II
II
II
II
II
,,
II
II
II
Dry Gas Temp.
°F
Inlet
92
inn
i?i
19Q
133
136
134
138
1 Ifl
l'iO
139
138
Outlet
00
Q&
inn
in 3
i no
112
112
ii'i
1 1 u
i ifi
HA
116
Pump
Vacuum
In. Hg
Gauge
is n
1*1 r\
16.0
^A n
Ifi 0
16 0
}£-S
16 S
Ifi ^
1A «;
16 5
Box
Temp.
°F
1 7^
n
ii
n
n
n
n
ii
n
M
ii
ii
ti
Impinger
Temp
°F
70
7n
70
70
7O
70
7P
70
7n
fiS
A^
65
Stack
Press
in. Hg
29 8
n
n
n
n
ti
n
n
n
n
n
n
n
n
Stack
Temp
°F
175
n
n
it
n
n
n
it
it
it
ii
n
it
1
Comments: off 09:2i power failure
NCAP-37 (12/67)
o
-Ui
-------�
Run No.
Location
Date
ASE-2
Bag Exh
9-1-71
PARTICULATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F
Bar. Press. "Hg
80
29.8
Assumed Moisture %
2%
Operator
Heater Box Setting, °F 250
Sample Box No. 4.
Meter Box No.
Probe Tip Dia., In. .5
Probe Length
Probe Heater Setting
65
Point
#,«
I
Clock
Time
Q9 :1°
1 1 -ns
n -is
11 ;25
11 ;1S
11 :A5
•ji • ^s
12>r>5
12 • 1^
1? '9q
12 • 35
1? "^
1 ?, i/»0
Dry Gas
Meter, CF
911 ;06
_
_
in/:o fin
Pi tot
in. HgO
AP
Orifice AH
in HoO
Desired L
Actual
4 0
II
II
II
II
II
II
II
II
II
II
II
Dry Gas Temp.
°F
Inlet
gn
86
\1K
1?A
111
ns
l^s
l^ft
1 ^S
1 ^S
IIS
136
Outlet
80
86
99
9S
inn
in£
ins
nn
nn
nn
110
_
110
Pump
Vacuum
In. Hg
Gauge
19 ^
19 5
]R n
17,S
17 S
17.S
1 7 S
17 *>
17.S
17 5
17.5
^
17 ^
Box
Temp.
°F
_i50
n
n
ii
n
M
n
n
M
It
It
II
II
Impinger
Temp
°F
65
60
.ftn
65
fiS
ftS
6S
7n
65
65
70
70
Stack
Press
in. Hg
29 8
it
it
ii
ti
ii
n
n
it
n
n
in
n
Stack
Tc;np
°r
150
175
17^
17S
17S
17S
175
175
175
175
175
17^
Comments: Off @ 09:26 power failure
NCAP-37 (12/67)
o
-------�
PARTICIPATE FIELD DATA
Run No. ANE-3
Location
Bag Exh
I
Date
9-1-71
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F 85
Bar. Press. "Hg 29.8
Assumed Moisture % 9
Operator Uo11
Sample Box No.
Meter Box No.
Heater Box Setting, °F250
Probe Tip Dia., In. .5
Probe Length 6
Probe Heater Setting .17°
Point
6'
Clock
Time
'14:34
14:44
1 A.5A
1 S-04
15 • 14
1S:24
15:34
i =;• AA
1 5 • ^ 4
lft *0.4
1 ft 1 1 '\
16-24'
16 t 3 '\
1ft «AA
1ft -"iA
1 7-nA
Dry Gas
Meter, CF
126.46
—
—
_
_
_
__
—
Pi tot
in. H20
Ap
Orifice
in Ho
Desired
AH
0
Actual
3.4
3.6
3 4
T.4
3 4
3.4
3.4
3.4
V4
3.4
3 4
3.2
3 2
M
it
ii
Dry Gas
°F
Inlet
118
133
137
14T
149
142
141
14ft
139
144
14ft
146
148
14ft
140
ISO
Temp.
Outlet
114
114
11^
1 19
122
122
123
125
125
125
12ft
128
130
132
130
130
Pump
Vacuum
In. Hg
Gauge
20.0
19.3
1Q 9
19.0
1« Q
19,0
19.0
19.0
19.0
19.0
IQ n
19.0
-[Q n
19.0
19.0
18.5
Box
Temp.
°F
250
II
II
•
II
II
It
II
II
II
II
II
II
II
II
II
Impinger
Tenip
°F
100
95
QJ
85
Hfl
80
80
85
80
85
fiS
90
QO
95
95
75
Stack
Press
in. Hg
29.8
n
M
n
n
n
n
n
n
ii
n
n
n
n
it
it
Stack
Tc.v.p
°r
175
ii
ii
n
n
ti
n
ti
ti
M
n
n
ii
M
1
" I
Comments:
17:14
17:24
310.46
146
120
119
134
115
109
19.0
19.0
19.0
75
75
85
II
It
II
II
II
II
o
-------�
PARTICULATE FIELD DATA
Run No. ACE-3
Location
Date -i
VERY IMPORTANT - FILL IN ALL BLANKS , Ambient Temp °F
Bag Exh
Read and record at the start of
each test point.
Bar. Press. "Hg 29-8
Assumed Moisture % 2
Operator
Blessine
Sample Box No. H_
Meter Box No. <
Heater Box Setting, °F 170
Probe Tip Dia., In.
Probe Length
.5
Probe Heater Setting
60
Point
6'
1
Clock
Time
14:32
14:42
14:57
i s-n?
11-17
IS-??
1 S- 1?
I1* '42
1S:S?
Ifl •<">?
lfi;12
1ft-??
Ifi--:*?
16:4?
16;S2
17;02
Dry Gas
Meter, CF
187.10
—
_
_
_
_
_
_
—
_
_
Pi tot
in. H20
AP
Orifice AH
in HoO
Desired '
Actual
L IL
ii
ii
ii
ii
ii
ft 0
s!s
5.5
•5.5
S.5
S.S
ii
ii
ii
Dry Gas Temp.
°F
Inlet
i in
126
iz^n
142
145
14^
1 A4
144
150
152
156
156
158
158
166
Outlet
lln
110
llfi
120
122
124
l?fi
126
125
124
130
130
132
132
136
Pump
Vacuum
In. Hg
Gauge
in
10
in
ln
ln
ln
in
18
18.1
18.1
18.1
18.0
18.0
18.0
18.0
Box
Temp.
°F
250
ii
it
ii
ii
ii
ii
ii
M
it
i;
ii
M
II
It
Impinger
Temp
°F
80
78
80
80
80
75
7n
70
70
70
70
70
70
70
65
Stack
Press
in. Hg
?Q fl
M
it
II
II
II
II
II
M
II
II
it
II
II
It
Stack
Temp
°r
17^
M
it
ti
ti
ii
ii
it
ii
it
M
ti
n_
ii ••
ii
17:12 - " 166 136 18.0 " 65 "
Comments: i?:22 - " 164 134 18.0 " 65 " "
17:32 401.16 5.5 170 140 18.0 " 70
NCAP- 37" (12/67)
7
'00.
-------�
PARTICULATE FIELD DATA
Run No. ASE-3
VERY IMPORTANT - FILL IN ALL BLANKS , Ambient Temp °F_86_
Location Bag Exh
Date -9-1-71
Read and record at the start of
each test point.
Bar. Press. "Hg 29.8
Assumed Moisture % 2
Operator Blessing
Heater Box Setting, °F 170
Sample Box No. 4__
Meter Box No. H
Probe Tip Dia., In. .5
Probe Length 6
Probe Heater Setting 60
Point
6'
i 9 HPC
Comments :
3 HRS
Clock
Time
14:10
14;40
14 *5n
i c .on
lq*ln
i "; .?n
1 ^ • 3n
1* •/in
]_R . =;n
IA .nn
IA .in
IA -?n
iA- in
1A.AO
ifi.sn
I7«nn
17:10
17:20
17:30
Dry Gas
Meter, CF
4R OA
_
•
_
_
264.30
Pi tot
in. HzO
AP
Orifice
in Ho
Desired *
AH
0
Actual
4 0
it
ii
it
ii
ii
it
ii
4 ^
n
ii
n
ii
it
n
ii
n
ii
ti
Dry Gas
°F
Inlet
96
"•18
1"*7
142
142
144
14^
1 4R
14A.
1 A7
146
147
1A&
TAft
146
146
&
155
Temp.
Outlet
96
inn
in A
112
11?
11^
118
1 9n
1 70
19?
1 92
1 99
199
122
121
121
ffl
125
Pump
Vacuum
In. Hg
Gauge
10 n
17 n
•)A R
16 q
1 A ^
]fi R
1ft n
ifi n
1Q S
1Q S
19 S
19 S
19 S
19. S
19. S
19. S
19.5
19.5
19.5
BOX
Temp.
°F
170
n
it
it
n
it
n
n
it
n
n
n
n
n
n
n
n
n
n
Impinger
Temp
°F
85
QS
RS
«n
7^
?n
AS
fiS
6^
6S
65
70
70
70
70
70
70
70
76
Stack
Press
in. Hg
29.8
n
n
n
ii
n
n
it
it
it
n
n
n
ii
n
n
n
n
ii
Stack
T<"^p
°F
170
17n
l^n
iftn
17°
1RO
iftn
1 80
180
17S
190
200
185
185
185 j
180 1
180
180
180
— A f . jy
NCAP-37 (12/67)
G
vo
-------�
Run No. 1
Location ABD-I
Date
.3-31-71
PARTICULATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F
86
Bar. Press. "Hg 29.8
Assumed Moisture %
Operator Baxley
Sample Box No. 3
Meter Box No. 3
Heater Box Setting, °F 250
Probe Tip D1a.f In.
Probe Length
3/16"
114
Probe Heater Setting
A
Point
5
A L
1
* 2
1
1
* 9
•*
/.
S
* 1
9
r 3
* L
Clock
Time
17:17
17-7?
17-77
17:32
17:37
17:42
17:47
i 7. ^9
I"7' 57
18:02
1 R-D7
1R-19
1R.17
1R-99
1R-97
Dry Gas
Meter, CF
7fifi R1
77n r\L
773 in
776.27
778.49
780.55
783.50
7«A fin
78° 37
7Q9 n7
7Q£ 6R
7Q7 ?S
7QQ R9
809.53
an s in
PHot
in. H£0
AP
,Rn
i nn
i nn
1 .00
.98
,PO.
.90
1 n9
on
i nn
Q5
.85
.99
.95
. 95
Orifice AH
in H00
Desired
,Rn
Qfi
Qft
.96
.95
.76
.88
1 I*1
92
.Qfi
.90
.82
.88
.92
.99
Actual
,Rn
Qfi
Qfi
.Qfi
.95
.76
.88
1 1^
.92
.96
90
.82
.88
.92
92
Dry Gas Temp.
°F
Inlet
R6
R6
RR
RR
88
96
100
100
100
102
102
102
100
100
100
Outlet
R6
R6
R4
84
84
86
88
88
88
100
93
93
92
92
92
Pump
Vacuum
In. Hg
Gauge
s
c;
1 1
9A
5
5
20
ln
17
25
10
15
5
15
20
Box
Temp.
°F
95n
9sn
95n
250
250
750
250
2^0
250
250
250
250
250
250
250
Impinger
Temp
°F
65
6^
65
7n
7n
7n
70
70
70
70
75
75
75
75
75
Stack
Press
in. Hg
29.8
Stuck
Tcirip
°F
11n
^lO
•^in
^1 5
^nn
^?n
35^
310
31,5
335
355
325
330
335
330
Comments: * Filter changed
NCAP-37 (12/67}
I
" t—'
o
-------�
ADB-1 Run //I Page 2 of 2 pages
Point
* 5
I
9
n i
A
"*
**•
Clock
Time
18:32
18:37
JR. 49
1R*47
1R-S9
Dry Gas
Meter, CF
808.46
810.88
«!? sn
81 * ''lO
R17 flfi
010 5P
Pi tot
in. H20
AP
.85
.55
05
85
R5
an
Orifice AH
in H00
Desired ""
.82
.56
92
80
RD
7R
1
Actual
.82
.56
92
80
RQ
- . 7«
Dry Gas Temp.
°F
Inlet
100
100
100
100
inn
inn
Outlet
92
92
92
92
on
on
Pump
Vacuum
In. Hg
'Gauge
15
10
13
12
1>;
1 S
Box
Temp.
°F
250
250
250
250
2sn
9sn
Impinger
Temp
°F
75
75
70
70
70
70
Stack
Press
in. Hg
Stack
Temp
°r
330
350
350
360
340
•*sn
;
1
>mments:
* Filter Change
:AP-37'(12/67)
-------�
Run No.
AKD-2
PARTICULATE FIELD DATA
IMPORTANT - FILL IN ALL BLANKS
Ambient Temp °F 90
Location AIR co NIAGARA
Date -9-1-71
Read and record at the start of
each test point.
Bar. Press. "Hg 29.8
Assumed Moisture % 4.1
Operator Baxley
Sample Box No.
Meter Box No.
Heater Box Setting, °F 250
Probe Tip Dia., In.
Probe Length
3/16"
11'41
Probe Heater Setting 60
Point
A 1
2
3
4
s
i
2
B 3
4
c
1
* 9
T
C 4
V
Clock
Time
09:10
09?1S
no . on
09 l25
OQ-10
nq?3s
n9'AQ
09 • '\ q
no. =;n
nq-ss
10 1 00
in. n<;
in-in
in-i s
10:20
Dry Gas
Meter, CF
819.62
891 Qfi
82/i 62
827 32
R°0 flfl
R-*9 41
R1A qi
837 65
RAn 30
RAI nn
g/|5 /(6
RA7 ^S
RSO. ^s
8S2.Q2
855.62
PI tot
in. H20
AP
7R
95
nc
90
82
R9
1 01
1 ni
QO
75
on
_qo
.qo
1.00
Orifice AH
in HoO
Desired
7S
92
o °
87
80
Rn
1- 00
1 On
.87
7/,
Sfi
.86
.86
.95
Actual
7S
92
no
87
80
an
Inn
:oo
.87
7/,
fifi
.86
r56
,95
Dry Gas Temp.
°F
Inlet
74
80
86
90
Q-J
94
94
94
QA
96
96
90
90
Outlet
lit.
T\
T /
74
7/,
76
80
8Q
80
82
90
90
88
88
Pump
Vacuum
In. Hg
Gauge
•;
c
ft
«;
^
£
18
24
24
2**
24
25
20
77
Box
Temp.
°F
2 SO
M
ii
ii
ii
ii
ii
ii
M
M
ii
ii
ii
ti
Impinger
Temp
°F
60
6°
(\(\
60
60
60
60
fin
60
fin
60
60
60
fin
Stack
Press
in. Hg
29.8
Stack
Tarip
°F
•^25
•*nn
VI1?
302
325
310
^fiS
3fiS
340
338
310
310
'^9'i
3AO •
1
i.iments:
** #3 imp. clogged at 10:30
* Filter Change
:AP-37'( 12/67}
o
-------�
Air Co Niagara Page 2 of 2
Point
i
7
•}
4
s
*~
Clock
Time
in«?s
10:30
10': 35
in. An
10 '7i5
Dry Gas
Meter, CF
RSR T7
860.74
863.30
afifi.in
868 57
fnn o?
P1tot
in. H20
AP
i .no
.62
.95
1 .00
R<;
R1;
Orifice
in Ho
Desired
.95
.60
.92
.95
R9
R9
AH
0
Actual
.95
.60
.92
.95
R?
R?
Dry Gas
°F
Inlet
90
90
90
90
90
90
Temp.
Outlet
88
88
88
88
fifi
86
Pump
Vacuum
In. Hg
'Gauge
— /
18
18
3
4
S
14
Box
Temp.
°F
_
M
ii
ii
it
ti
H
Impinger
Temp
°F
65
65
65
65
65
65
Stack
Press
in. Hg
Stack
Tc:r,p
°F
330
330
308
318
315
315
1
;
I
>ir.ments:
:AP-37'(12/67)
o
-------�
Run No.
Location
bate
ABD-3
PARTICIPATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS , Ambient Temp °F 90
- Niagara Falls
9-1-71
Read and record at the start of
each test point.
Bar. Press. "Hg ?Q ft
Assumed Moisture % 4.1
Operator
Heater Box Setting, °F 250
Sample Box No.
Meter Box No.
Probe Tip Dla.. In. 3/16"
Probe Length ii'4"
Probe Heater Setting 60
Point
^
A ?
3
4
5
1
2
B 3
4
«>
4
s
Clock
Tims
l'i i CiO
14- AS
I'll 50
1A-5S
1 5 .QQ
i * .nc
15ilQ
I6* *15
1^ • 20
1^ *25
is.™
11 *» • 3^
15:40
15:45
15:50
IS'SS
Dry Gas
Meter, CF
R7fl QR
873. S3
876.1Q
R7R 7S
881.35
883.80
886.56
RRQ nn
RQ] RI
894. 7n
RQfi RQ
ftqg ^n
902.20
905.03
907.71
910.00
Pi tot
in. H20
AP
10
^f5
.90
.98
.80
1.10
1.10
.95
1.00
.95
.85
1.10
1.10
i nn
i nn
Orifice
in Ho
Desired "
• \- •
.86
.92
.86
,05
.76
l.OS
1.05.
.92
.94
.Q2
.at.
1 05
ins
OA
'J^
,88.
AH
0
Actual
RA
Q9
R£
.QS
.76
i.ns
1.05
.92
.94
.92
.84
1.05
1.05
..94
.88
Dry Gas
°F
Inlet
Rfi
RR
QA
ion
102
10A
102
100
108
110
110
112
112
110
liu
Temp.
Outlet
R£
Rfi
ftfi
90
92
92
96
94
98
100
100
102
102
100
100
Pump
Vacuum
In. Hg
Gauge
s
£
.1.1
15
18
25
18
17
20
6
6
8
10
15
2
Box
Temp.
°F
?sn
11
ii
ii
ii
H
ti
H
H
ii
M
H
11
H
"
Impinger
Temp
°F
f,r\
fin
fin
H
M
M
ii
H
11
H
ti
H
^ r
65
A1
Stack
Press
in. Hg
29.8
Stack
Tcr.p
°F
33S
3sn
3SS
3fin
3°S
3S5
33S
330
3SS
27n
33n
360 i
328 1
5iT.tr.e ts:
:AP-37'(12/67)
a
-------�
Air Co, Niagara Fall^age 2 pf 2
Point
i
2
rn
5
"^
Clock
Tims
i6:nn
16:05
16:10
lft* 1 ^
16i°0
Dry Gas
Meter, CF
912.38
915 r 14
917.84
q?n An
922 99
Pi tot
in. H20
AP
.70
1.10
1.05
QS
8n
Orifice AH
in HoO
Desired "
.64
.98
.95
.86
74
1
Actual
.64
.98
.95
;86
74
Dry Gas Temp.
°F
Inlet
110
110
110
110
110
Outlet
100
100
102
102
102
Pump
Vacuum
In. Hg
•Gauge
2
3
4
9
12
Box
Temp.
°F
250
"
11
ii
it
Impinger
Temp
°F
65
65
65
65
65
Stack
Press
in. Hg
Stack
Tcirip
°r
305
31U
3Zi
365
345
i
;
I
jmrcents:
:AP-37'(12/67)
o
M
Ul
-------�
PARTICULATE FIELD DATA
Run NO. Metals/Part.
Location ANE - 4M
I
Date
9-2-71
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F
80
Bar. Press. "Hg 29-8
Assumed Moisture % 2
Operator McReynolds
Sample Box No.
Meter Box No.
Heater Box Setting, °F 170
Probe Tip Dia., In. ~^__
Probe Length 5
Probe Heater Setting 60
Point
4
1
2
3
Clock
Time
1 0 ; 1 ?
10:27
10:42
in?S7
11:12
11:27
11:42
11:57
12:12
12:27
12:42
12:57
13:12
13:27
13:42
13:57
Dry Gas
Meter, CF
311 n4
_
— „
_
_
_
<—
_
_
_
_
_
_
-
PHot
in. H20
AP
Orifice AH
in H00
Desired "
Actual
i 3
i i
i i
3 3
3.1
3. 3
3.1
3.3
3.3
3.3
3.3
3.1
3.3
3.3
3.3
3.3
Dry Gas Temp.
°F
Inlet
82
inn
10A
108
ins
ina
ins
108.
103
102
ir>2
in?
103
108
106
106
Outlet
78
80
86
88
88
qn
Q?
Q9
QO
90
QO
Qn
QO
QO
QO
92
Pump
Vacuum
In. Hg
Gauge
19.5
19 5
19. S
1Q.S
Jg.S
1Q J
1Q S
1Q 1
1Q 1
1Q.3
1Q 1
1Q 1
1Q.3
1Q.3
1Q.3
19.3
Box
Temp.
°F
i ?n
it
it
ii
u
ti
ti
it
it
it
u
M
ti
it
u
it
Impinger
Temp
°F
fin
7S
7S
an
?n
JO
7n
7n
7n
7n
7n
7n
fiS
65
65
65
Stack
Press
in. Hg
?Q S
n
it
u
it
M
u
it
u
u
it
u
it
it
it
u
Stack
Tc^p
°F
170
it
it
u
u
u
u
u
M
u
ti
it
u
M
u '
11
Comments:
14:12
550.50
3.3
102
90
19.3
170
70
NCAP-37 (12/67)
-------�
PARTICULATE FIELD DATA
Run No. ACE
Location
Date
VERY IMPORTANT - FILL IN ALL BLANKS , Ambient Temp °F 80
Center Exhaust
9-2-7l_
Read and record at the start of
each test point.
Assumed Moisture
Operator Blessing
Sample Box No. 4
Meter Box No. 4
Probe Length
'Hg 2Q R
;ure % 2
ittlng, °F
170
., In. ~
5
Setting
70
Point
i
Clock
Time
10:10
10:25
10:40
10:55
11:10
11:25
11:40
11:55
12:10
12:25
17; AD
12:55
13:10
13:25
13:40
13:55
Dry Gas
Meter, CF
403.A9
_
_
_
_
_
_
_
_
_
_
_
—
—
1
P1tot
In. H20
AP
Orifice
In Ho
Desired
AH
0
Actual
/, /,
4 4
4.4
4,4
4.4
4.S
4.5
ii
ti
ii
4 ^
L L
4.4
4.4
4.4
4.4
Dry Gas
°F
Inlet
90
107
120
125
1 9ft
1 33
1 37
1?8
123
122
191
1 9S
19?
124
i?n
120
Temp.
Outlet
80
go
RQ
Q4
QR
1O9
IP3-
109
101
99
98
QR
9R
QR
100
TOO
Pump
Vacuum
In. Hg
Gauge
90 5
9n s
90 S
90. 5
90 S
ti
?n s
90. 5
20 S
20 q
9n s
9n. s
9n. s
90. S
90.5
Box
Temp.
°F
1 7n
n
ii
n
n
i
i
i
i
i
,
i
i
i
i
t
Impinger
Temp
°F
65
70
?n
7n
70
AC;
A1
A^
fiS
fiS
70
70
fin
fin
65
65
Stack
Press
in. Hg
29.8
ii
n
n
it
n
n
n
it
it
n
n
n
ii
n
n
Stack
Tc::ip
°F
175
n
n
n
it
n
n
n
n
n
n
n
n
1
!
-
14:10
Comments:
NCAP-37 (12/67)
671.49
i
>-•
'VJ
-------�
PARTICULATE FIELD DATA
Run NO.ASE 4M
Locati Oflouth Bag Exh
Date • 9-2-71
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F 80
Bar. Press. "Hg 29.8
Assumed Moisture %
Operator Blessing
Sample Box No. 4
Meter Box No. H
Heater Box Setting, °F 170
Probe Tip D1a., In.— -
Probe Length 5
Probe Heater Setting
70
Point
4 in
Clock
Time
10:10
10:25
10:40
10:55
11:10
11:25
11:40
11:55
12:10
12:25
12:45
12:S5
13:10
13;25
13:40
13:55
Dry Gas
Meter. CF
264.35
-
-
-
_
_
_
—
-
—
-
_
_
—
_
—
Pi tot
in. H20
AP
Orifice AH
in HoO
Desired *
Actual
4.5
4.5
4.5
4.5
4.5
4.6
4.6
4.6
4.6
4.6
4.6
4.6
4.6
4.6
4.6
4.6
Dry Gas Temp.
°F
Inlet
76
106
116
120
121
122
126
127
127
129
126
12S
128
126
127
126
Outlet
77
82
89
94
96
98
100
101
101
102
101
1Q1
100
100
98
101
Pump
Vacuum
In. Hg
Gauge
20.0
20.0
20.0
20.0
20.0
19.0
19.0
19.0
19.0
19.0
19.0
19.0
19.0
19.0
19.0
19.0
Box
Temp.
°F
170
. II
tl
II
It
It
II
It
II
II
II
II
II
II
II
II
Impinger
Temp
°F
80
80
80
75
70
65
65
65
65
65
65
70
60
60
60
65
Stack
Press
1n. Hg
29.8
ti
ii
it
H
it
it
H
it
it
ti
it
ii
it
H
ii
Stack
Temp
°r
170
155
155
155
130
170
165
165
165
150
170
UO
170
160
165 1
180
14:10
Comments:
NCAP-37 (12/67)
558.32
4.6
127
100
19.0
65
175
.0
M
00
-------�
Run No.
1-2-3
Locati on INLET ABD Metals 4-5-6
Date -9-2-71
Operator Baxiev
Sample Box No. 3
Meter Box No. 3
PARTICIPATE FIELD DATA
VERY IMPORTANT - FILL IN ALL BLANKS
Read and record at the start of
each test point.
Ambient Temp °F
Bar. Press. "Hg 29-8
Assumed Moisture %
Heater Box Setting, °F_
Probe Tip Dia., In.
Probe Length
5'
Probe Heater Setting . 65>
Point
BT~!
R-2
I*-1*
Clock
Time
no-is
- 01 - no . .
09:35
09:41
OQ *sn
nQ-sv
Dry Gas
Meter, CF
Q99 Qf)
935.72
935.72
939.65
QV1 fiS
QAfi 1 7
PHot
1n. H20
AP
i ^n
1.30
1.30
1.00
i ™
1 .30
Orifice AH
In HoO
Desired
Actual
Dry Gas Temp.
°F
Inlet
7n
86
84
86
76
88
Outlet
7n
86
78
80
76
80
Pump
Vacuum
In. Hg
Gauge
7
22
2
22
2
22
BOX
Temp.
°F
9^n
Impinger
Temp
°F
AH
Stack
Press
in. Hg
Stack
Tc:np
°r
•*9n
Comments:
NCAP-37 (12/67)
• o
-------�
Dates-31-71
PARTICULATE CLEANUP SHEET
Plant: AIRCO
Run number: ANF.-I AP.R-I ASR-T
°Perator:
Sample box number:
Location of sample port: EXHAUST
Barometric pressure:
Ambient temperature:
195/195/203
Volume after sampling ml Container No.
Impinger prefilled with200 ml Extra No.
Volume collected -5/-5 ml/3
Ether-chloroform extraction
of impinger water
Impinger water residue
mg
mg
Impingers and back half of'
filter, acetone v/ash:
Container No.
Extra No.
Weight results_
mg
Dry probe and cyclone catch: Container No._
Extra No.
Weight results
mg
Probe, cyclone, flask, and
front half of filter,
acetone wash:
Container No._
Extra No.
Weight results
QQQQ85
PQQQ96 ACE-1
000100 ASE-1
I
Total particulate weight
mg
Filter Papers and Dry Filter Particulate
Filter number Container no. Filter number Container no.
Filter particulate
weigh t mg
mg
Silica Gel
Weight after test:
Weight before test:
Moisture weight collected:
Container number: 1.
ANE-1 ACE-1 ASE-1
172.3 196.3 194.6
2.
3.
4.
Moisture total
jgm
Sample number:
Method determination-^
Comments:
Analyze for:
D-20
-------�
PARTICULATE CLEANUP SHEET
Date: 9-1-73, Plant: A-rnr.n
Run number: ANE-2 ACE-2 ASE-2 Location of sample port: EXHAUST
Operator: Blessing,McReynolds Barometric pressure:
Sample box number: 2 • ' Ambient temperature:
Impinger H20 190/i86/i95
Volume after sampling ml Container No. Ether-chloroform extraction
Impinger prefilled with_200_jnl Extra No. of 1mP1n9er water m*
Volume collected -10/-14 ml -5 Impinger water residue mg
Impingers and back half of Container No.
filter, acetone wash: Extrfl NQ< We1ght results mg
Dry probe and cyclone catch: Container No.
Extra No. Weight results mg
Probe, cyclone, flask, and Container No.
:"^fnter- **«"°- MJ* —"'-
Filter Papers and Dry Filter Particulate
Filter number Container no. Filter number Container no.
I
Q1Q& ANE-2 |
01 AT AfF—2 ......
vjxy/^ ^ — -1 ^ T* i i j i ,_ -i..,-, - -i- -_-m_Lf_i-, - - Fiitpv* my*t"if*Uif^tP
?FM-M ASK-7 | weight mg
Total particulate weight mg
S11iCa Gel ASE-1 ACE-1 ANE-1
Weight after test:
Weight before test: 165.7 181.8 184.4
Moisture weight collected: Moisture total gm
Container number: 1. 2. 3. 4.
Sample number: Analyze for:
Method determination:
Comments:
D-21
-------�
PARTICULATE CLEANUP SHEET
*
Date: 9/1/73 Plant:
Run number - JME-3 ACE-3 ASE-3 Location of sample port: EXHAUST
Operator- Blessing. McReynolds Barometric pressure:
Sample box number: 5 ' Ambient temperature:
Impinger H20 187/18o/18i
Volume after sampling _ ml Container No. _ Ether-chloroform extraction
Impinger prefilled with_2flQ_ml Extra No. _ _ of 1mP1n9er water
Volume collected -13/-2Q _ ml-19 Impinger water residue _ _ mg
Impingers and back half of Container No. _
filter, acetone wash: Extra No> _ Weight results _ mg
Dry probe and cyclone catch: Container No. _
Extra No. _ Weight results ___ mg
Probe, cyclone, flask, and Container No. _
result.
Filter Papers and Dry Filter Particulate
Filter number Container no. Filter number Container no.
I
ANR 3 | _ _
Q9J -- A£Ez3. - , -- Filter particulate
092 __ ASE-3 | _ __ _ weight _ mg
Total particulate weight __ mg
Silica Gel ANE-3 ACE-3
Weight after test:
Weight before test: 177.7 197.7 175.6
Moisture weight collected: Moisture total gm
Container number: 1. 2. 3. 4.
Sample number: Analyze for:
Method determination:
Comments:
D-22
-------�
Date: 8-31-71
Run number:
Operator: GONZALEZ
Sample box number:
PARTICULATE CLEANUP SHEET
Plant:
AIRCO
Location of sample port: INLET DUCT
Barometric pressure:
Ambient temperature:
Impinger
Volume after sampling 205 ml
Impinger prefilled with 2QQ ml
Volume collected «= ml
Container No,
Extra No.
Ether-chloroform extraction
of impinger water
Impinger water residue
mg
mg
Impingers and back half of
filter, acetone wash:
Container No.
Extra No.
Weight results
mg
Dry probe and cyclone catch: Container
Extra No.
Weight results
mg
Probe, cyclone, flask, and
front half of filter,
acetone wash:
Container No.
Extra No.
Weight results
mg
Filter Papers and Dry Filter Particulate
Filter number Container no.
Filter number Container no.
000087 I
—000088 —, I
•7PM-77A
000086
Filter particulate
weigh t
Total particulate weight
_mg
mg
Silica Gel
Weight after test:
Weight before test: 169.0
Moisture weight collected:
Container number: 1. 2.
4.
Moisture total
_gm
Sample number:
Method determination:
Comments:
Analyze for:
D-23
-------�
Date: 9-1-71
PARTICULATE CLEANUP SHEET
Plant: AIRCO
Run number:
APT>—9
Operator: rrtN7.AT.R7
Sample box number:
Location of sample port: INLET
Barometric pressure:
Ambient temperature:
Impinger
Volume after sampling 206 ml
Impinger prefilled vrith 200 ml
Volume collected 6 ml
Container No.
Extra No.
Ether-chloroform extraction
of impinger water
Impinger water residue
_mg
mg
Impingers and back half of
filter, acetone wash:
Container No.
Extra No.
Weight results
mg
Dry probe and cyclone catch:
Container No.
Extra No.
Weight results
_mg
Probe, cyclone, flask, and
front half of filter,
acetone wash:
Container No.
Extra No.
Weight results
nnnnos
nnm
I
Filter particulate
weight
Total particulate weight
_mg
Filter Papers and Dry Filter Particulate
Filter number Container no. Filter number Container no.
I
_mg
mg
Silica Gel
Weight after test:
Weight before test:
Moisture weight collected:
Container number: 1.
2.
3.
Moisture total
Sample number:
Method determination:
Comments: FILTER AFTER IMPINGERS
Analyze for:
D-24
-------�
Date: 9-1-71
PARTICULATE CLEANUP SHEET
Plant: AIRCO
Run number:
Operator: GONZALEZ
Sample box number:4_
Location of sample port: INLET
Barometric pressure:
Ambient temperature:
Impinger
Volume after sampling 206 ml Container Mo._
Impinger prefilled withzQQ ml Extra No.
Volume collected 6 ml
Ether-chloroform extraction
of impinger water
Impinger water residue_
_mg
mg
Impingers and back half of
filter, acetone wash;
Container No.
Extra No.
Weight results
_mg
Dry probe and cyclone catch: Container No._
Extra No.
Weight results
mg
Probe, cyclone, flask, and
front half of filter,
acetone wash:
Container No._
Extra No.
Weight results
Filter Papers and Dry Filter Particulate
Filter number Container no. Filter number Container no.
I
5 I
QQQ15Q
OQQ153
I
Filter particulate
weight
Total particulate weight
_mg
mg
Silica Gel
Weight after test:
Weight before test: 183.5
Moisture weight collected:
Container number: 1. 2.
Moisture total
gm
3.
4.
Sample number:
Method determination:
Comments: FILTER AFTER IMPINGER
Analyze for:
D-25
-------�
GAS SAMPLING FIELD DATA
Material Sampled for
Date Q.-I-71 •
Plant AIRCO
Bar. Pressure 29.8
Ambient Temp. 85
Run No. ASE-I
Power Stat Setting NA
Filter Used: Yes x Nd
Operator BLESSING
so_
Location
1lHq Cornnents:
°F
GLASS WOOL
NIAGARA FALLS
CLOCK
TIME
is™ •
1SS1
1603
1615
1627
IfilQ
METER (Ft.3)
fin, fin
64 sn
67.52
70.62
74.30
7«1R
VACUUM
IN HC *•'
NA
A
*
* t
'
METER TEMPERATURE
10^
106
'" 108
108
108
108
Comments:
PUMP WAS BEFORE METER IN THE SAMPLE TRAIN
NCAP-36 (12/67)
r
-26
-------�
Material Sampled for
Date 9-2-71
GAS SAMPLING FIELD DATA
so
Plant AIRCO
Location NIAGARA FALLS
Bar. Pressure 9Q
11 Hq Consents:
Ambient Temp. 85
Run No.
°F
AGfi-J
Power Stat Setting
Filter Used: Yes x Nd
Operator BLESSINR
GLASS WOOL
Comments:
NCAP-36 (12/67)
CLOCK
TIME
1032"
10^4
insfi
1108
1120
J1^2
METER (Ft.3)
155.50
156. Q5
ISfi 60
15 7.' 14
157.60
IRft.10
VACUUM
IN He -'
1.5
1.5
IS *
•
•1.5
1-.5
1 T^
METER TFMPERATURE
84
8A
' '" fi-i
84
84
84
D-27,
-------�
GAS SAMPLING FIELD DATA
Material Sampled for so^
Date
Plant
QJ9-71
Bar. Pressure
29 _j
Location NTAHABA VAT.T.S
Comments:
Ambient Temp. 85
Run No.
°F
ANE 1
Power Stat Setting
Filter Used: Yes_J£ Ho GLASS WOOL
Operator
DLE33IN6
CLOCK
TIME
1239
1251
i •*! s
1327
133°
r-
METER (Ft.3)
158.82
160.60
Ifil.ys
162 , \ o
Ifi2 78
VACUUM
IN Hg »•'
1.6X
1.6
16 '
i
1.6
1 6
METER TEMPERATURE
82
84
R4
84
86
Comments:
NCAP-36 (12/67)
D-21
-------�
APPENDIX E
1. STANDARD SAMPLING PROCEDURES
2. CLEANUP AND ANALYTICAL PROCEDURES
-------�
APPENDIX E. 1
STANDARD SAMPLING PROCEDURES
PARTICULATE SAMPLING
In an unstable operation a trial run is conducted. Otherwise,
preliminary data are obtained for gas velocity, temperature and other
variables which might affect the isokinetic sampling rate. Four 5-
point, equal area traverses were selected as being most appropriate
for the conditions encountered at the exhaust duct. Three single points
were selected at the baghouse exit. Each sampling was designed to cover
one complete operating and tapping cycle, as a minimum.
Particulate samples were obtained using the equipment and test
procedures as stipulated in "Sample Collection Procedures," published
by GAP. The sampling train was basically the same as that designed
by the Control Development Program of OAP (formerly the Air Pollution
Control Office), "Gas Stack Sampling Improved and Simplified with
New Equipment," and described in Paper No. 67-119, presented at the
Air Pollution Control Association meeting in June 1967, Cleveland,
Ohio.
The sample gases were drawn into the all-glass sampling train
through a button-hook stainless steel nozzle with a diameter of 0.1875
inch. An incoloy probe was fitted inside the stainless steel sheath
with a probe heating element. The probe was connected to a glass
cyclone and an Erlenmeyer flask to collect the solids from the cyclone.
The sampled gases passed from the cyclone through a tared 2-1/2 inch
diameter MSA 1106BH glass fiber filter. This filter and the cyclone
E-l
-------�
were enclosed in a heated box which was maintained near 250°F.
After the first test the filter was moved to a position after the first
three impingers (See discussion). The filter holder was connected to
an impinger train consisting of four Greenburg-Smith impingers with the
high velocity tip removed from the first impinger. The second impinger
was used with the tip while the third and fourth impingers were modified
as the first. The first two impingers each contained a measured volume
(100 ml) of distilled, deionized water. The third impinger was used
dry and the fourth impinger contained approximately 175 grams of silica
gel. The sampling train exit was connected, in line, to a vacuum gauge,
a leakless vacuum pump, a dry gas meter, and a calibrated orifice. The
calibrated orifice differential was measured with an inclined-vertical
manometer. Velocity variations at the sampling point were constantly
monitored by a pitot tube connected to the probe sheath. The sampling train,
with probe and nozzle attached, was leak tested prior to each test.
Isokinetic sampling was maintained at the exhaust duct by appropriate
adjustment of the sampling rate as indicated by the pressure drop across
the orifice following the dry gas meter. The necessary orifice pressure
differential was determined by using the nomographs presented in APCA
Paper No. 67-119. This nomograph related stack gas velocity, temperature,
and moisture content to the flow rate required for isokinetic sampling.
Isokinetic sampling was not attempted on the baghouse outlet (see discussion),
E-2
-------�
SULFUR DIOXIDE SAMPLING
Sulfur dioxide emission tests were conducted at the same location
as the particulate tests. The sample gas was drawn through a glass
wool filter into a probe followed by a coarse frit midget impinger and
a second glass wool filter. The filter led to three midget impingers
in an ice bath followed in turn by a silica gel tube drier, vacuum
gauge, valve, leakless pump with by-pass valve, dry gas meter, rate
meter, and pitot tube with manometer.
The midget bubbler contained 15 ml of 80 percent isopropyl alcohol.
The first two midget impingers contained 15 ml of 3 percent H 0 solution
and the third was operated dry. A dry gas meter with vacuum gauge and
a pump followed the impingers. Temperatures, vacuum and gas meter readings
were taken and tabulated in order to calculate standard volumes. After
sampling, the train was purged with clean air in order to carry over any
S0? trapped in the isopropyl.
ORSAT SAMPLING
An integrated gas sample was obtained with a mylar bag and a peristaltic
pump with adjustable flow rate. The gases were filtered and cooled prior
to reaching an all plastic and glass flow meter where the sampling rate
was monitored. Gas samples were taken during the same period during which
velocities, temperatures, and particulate samples were obtained. Analyses
were performed at the site immediately after each sample was collected.
PARTICLE SIZING
The Brinks cascade impactor, followed by a 47 millimeter glass fiber
filter, was mounted on a probe and connected to a vacuum pump by a length
E-3
-------�
of rubber tubing. The inlet side of the pump was fitted with a vacuum
gauge calibrated in inches of mercury and a flow controlling valve. The
outlet side of the pump was connected to a dry gas meter when samples were
collected longer than 5 minutes.
Prior to collecting samples, the Brinks impactor was calibrated to
determine air flow rates by connecting it in series with a vacuum pump
with a vacuum gauge, and a dry gas meter.
The collector was grounded to prevent electrostatic deposition of
particles. It was placed into the stack with the nozzle covered to allow
it to thermally equilibrate prior to sampling. The sample was then
collected.
E-4
-------�
APPENDIX E.2
CLEANUP AND ANALYTICAL PROCEDURES
CLEANUP (EPA PARTICULATE TRAIN)
Probe, Nozzle, Cyclone, and Front Half of Filter Holder
The nozzle, probe, cyclone, flask, and front half of the filter
holder were washed with reagent grade acetone. Washings were collected
in a container and transported to the laboratory for analysis. A rubber
policemen was used with the acetone to remove and particles adhering to
the cyclone walls or the flask. The reagent acetone used for washing
was tested to determine the blank or residue upon evaporation.
Filter
The tared circular MSA type 1106BH filter paper was carefully
removed from the fritted glass support and transferred to a glass petri
dish for later weighing.
Impingers
Water in the first three impingers (the original water plus the
condensate) was measured, then emptied into a polyethylene container.
The impingers were then water washed; the washings were combined with
the condensate and the original water.
Acetone Train Wash
The rear half of the filter holder, including the fritted glass
support, the impingers, and impinger connections up to but excluding
the fourth impingers, were washed with acetone. These washings were
collected in a glass bottle and sealed for later analysis. On those
samples where the filter was after the impingers, the filter holder wash-
ings were added to this portion of the sample.
E-5
-------�
Silica Gel
Silica gel was transferred (dry) from the fourth impinger to
an airtight container and sealed. The impinger was then washed with
acetone, the acetone being discarded because it contained fine silica
gel particles.
CLEANUP (S02 TRAIN)
The impinger containing 80 percent isopropyl alcohol was discarded
and the impingers containing 3 percent H?0? saved. These contained SO
gas in the form of H?SO,. A glass jar was used as a sample container
for transportation to the laboratory for analysis.
ANALYTICAL PROCEDURES (EPA PARTICIPATE TRAIN)
Acetone Washings
The acetone washings from the nozzle, probe, cyclone and flask;
from the front and back of the filter; and from the impinger train
were analyzed separately by evaporation and drying at ambient tempera-
tures.
Filter Particulate
The filter and particulate collected thereon were dried for 24
hours in a desiccator at ambient temperature and weighed. Tare weight
of the filter was then deducted.
Impinger Water
Water collected in the impingers, along with the water washings of
the impingers, was extracted with ether and chloroform. The extracts
were transferred to a tared dish and evaporated to dryness at room
E-6
-------�
temperature. After extraction, the remaining water and solvent were
evaporated to dryness on a steam bath and this additional net weight
was added to the total weight of particulate matter.
Analysis-Orsat Measurements
Orsat measurements for determination of carbon dioxide, oxygen
and carbon monoxide were made using a Burrell Industrial Gas Analyzer.
Analysis-(SO Train)
S0» samples were analyzed by the Shell Development method except
that barium perchlorate was used instead of barium chloride (as in the
EPA proposed source testing Method 7) because of the sharper titration
end point obtainable with the former reagent.
Analysis - Particle Sizes
The individual pre-weighed impactor plates were removed and weighed
to the nearest 0.1 milligram. The tared glass fiber filter was also weighed.
The weight gains represent particle size fractions.
E-7
-------�
APPENDIX F
LABORATORY REPORT
-------�
VL f\ /'£
SAMPLES
NO.
LOCATION and
SAMPLE NO.
1 // £ -
SAl-IPLE
WEIGHT
TIT.
ALIQ.
^2; ici
ALIQ
•«*-/
?7'»*
31 ,?
U
,3
, S~
A S£ - .3
nt
U01.0
4/i/£ - 2
,7
7
- 2
^r
-------�
SAMPLES
Tc>ic I
CR
NO.
LOCATION and
SAMPLE NO.
SAMPI£
WEIGHT
TIT.
ALIQ.
KG id
ALIQ
2
L_
79.37 f
O.Ot I £
6,00 30
v.boi *
C- -3
0 Co
o.t>t 7 i
6.6/77
0.0 2 It,
o.o ^ /7
O.&QCk
0,01-i 3
id. d i
.01 S
. c /
fi
**.///7
0.00 !t>cf
0,60 t>f
fi
6,01 1
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ftce-i
75-
A se-1
-
0.60/ 7
•12
A
- 2
?"o
77. vn '
KSH
./S'
U
Project: No.
Collection Date 8/1/. " ^/J
Analysis Date
F-2
-------�
SAKPIES
1 / C
~$ i* I
CR
NO.
LOCATION and
SAMPLE NO.
V
SAlffLE
WEIGHT
TIT.
ALIQ.
ALIQ
(C'f1
' 3
tfc-
AM*
.c ?.: -.'
6.60/ 1
77.173/
L_
£- 2
. ^ -3 .^ '
- 2
, 0
b.U
11
L_
I
&lf2-
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0,00 1$
To
ftce-f
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0,00/
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6, £>'/
o, j ?~
- 3
13
\stf
6.1 W f-
(5 ,
6,131 1
Project No.
Collection Date
B/3/^
Analysis Date
F-3
-------�
er
NO.
LOCATION and
SAMPLE NO.
WEIGHT
ni.
ALIQ.
MS itj
ALIQ
L
1
4*6*7
0,663 £
L
[_
n
i_
Project No.
Collection Date
2/*/z/
Analysis Date ?/2?/?/
-------�
SAMPLES
ICR
NO.
LOCATION and
SAMPLE NO.
TIT.
ALIQ.
MS i
ALIQ
L
Grf* ;-
tt.flo*-
17.
W.FM
i
*>
a?./ a
w
0,
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0, / fi I
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11.
#& I I
0.17ft
tro
1131
o
000103
ro
JU./
L
Project No.
Collection Date_
Analysis Date __
F-5
-------�
SAMPLES
G.F. FILTE:
Told co^
NO.
LOCATION and
SAMPLE NO.
TIT.
ALIQ.
MG i
ALIQ
000 106,
JCF- 3
OOOO^I
- 3
O.IT7 1
\ nil
^.7ft./9
L
ooo lay
o . 115*1
000
tiCF- 2.
Z FH -*1
C '
Aut -
0.117$
?
tce~!
0.116
oooo '96
a./fdf*i
a v
H
L_|
Project No.
Collection Date
~ /
Analysis Date
< !Z^ /?
F-6
-------�
SAMPLES
NO.
LOCATION and
SAMPLE NO.
SAHPU3
WEIGHT
TIT.
ALIQ.
*2G iri
AIIQ
A»6 ~ /
0-
a.i
2-f
"100
L.
L
M
Project No,
/ IK | 0. 00462 M
Collection Date Y2/7
Analysis Date t
-------�
>C
SAMPLES
Project No
Collection Date_
Analysis Date
F-.8
-------�
SAMPLES
fAuS
NO.
LOCATION and
SAMPLE NO.
SAliPLE
IffilGHT
TIT.
ALIQ.
KG it*
ALIQ
2JT
- 3
6,66 Of-
~ 3
d,
Ase -
7 7.
4-6.00 If
o.ool
P.60 ft
>6 Of I
, 0 0
L.
- z
l
^- — "7
71.&30
0,00
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79.
7?.
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vx
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6,0011
iEffiS" ™t^fr!t^f^ -*^f»*^Lagj
-r£
.57^1
•r
N
SBlf
t "U/i
06^
t
b.06 /?."
Project No.
Collection Date_
Analysis Date __
F-9
-------�
APPENDIX G
TEST LOGS
-------�
TEST LOG
Date Samples Performed
8-30-71 Arrive. Equipment unpacked
8-31-71 Equipment set up. One set particulate samples
completed, inlet and outlet. One series of
three particle size samples completed on baghouse
outlet.
9-1-71 Two sets of particulate samples completed at inlet
and outlet. Three baghouse outlet and 5 furnace
exhaust particle size samples taken. Combustion
gas samples (inlet and outlet) taken and analyzed.
One SO- sample taken at baghouse outlet. Part of
crew return home.
9-2-71 Two SO- samples taken at baghouse outlet and 4
furnace exhaust particle size samples taken. Three
baghouse outlet and 3 furnace exhaust particulate
samples taken for metals analysis. Equipment
packed and remainder of crew returned home.
Furnace number 9 was within normal operating parameters during testing.
Tapping schedule each day was: 10:00 A.M.
11:50 A.M.
1:40 P.M.
3:30 P.M.
5:20 P.M.
7:10 P.M.
9:00 P.M.
G-l
-------�
APPENDIX H
RELATED REPORTS
-------�
Related reports covering emissions from reactive metals furnaces,
under this same contract for the Environmental Protection Agency are
as follows:
Test Number Survey Location
FA-1
FA-2
FA-3
FA-4
FA-5
Foote Mineral Co.,
Steubenville, Ohio
Emission
Control Device
None
Union Carbide Corp., Venturi
Marietta, Ohio Scrubber
AIRCO Alloys and Baghouse
Carbide, Niagara Falls,
New York
AIRCO,
Charleston, S. C.
Electrostatic
Precipitator
Status
Issued Aug., 1971
Issued Oct. , 1971
This Report
In progress
Future
H-l
-------�
APPENDIX I
PROJECT PARTICIPANTS AND TITLES
-------�
R. N. Allen, P. E., Project Leader
N. A. Blessing, Chemist
C. C. Gonzalez, Chemist
T. E. Eggleston, Project Engineer
G. B. Patchell, Test & Development Specialist
(Partcle Size Determination)
L. W. Baxley, Technician
J. Avery, Technician
J. McReynolds, Technician
W. Hall, Technician
METALS ANALYSIS
J. R. Ogren, Program Manager
D. F. Carroll
M. L. Kraft
W. B. Hewitt
1-1
-------�
APPENDIX J
PARTICLE SIZING
DATA & RESULTS
-------�
EXPLANATION OF DATA
The field data sheets are included in Appendix J~2. The characteristic
diameter of an aerosol particle for each impactor stage (i.e., Dpc) has
been calculated for pressure drops across the impactor of five inches
of mercury and 10 inches of mercury, assuming particles of unit density
(1 gram/cubic centimeter), using the equation described by J. A. Brink,
Jr. * The characteristic diameters are as follows:
For a Pressure Drop of Five Inches
Of Mercury Across the Impactor
Stage No.
1
2
3
4
5
Dpc
micron
3.40
2.00
1.36
0.69
0.42
For a Pressure Drop of Ten Inches
Of Mercury Across the Impactor
Dpc
;e No.
1
2
3
4
5
micron
3.06
1.80
1.23
0.63
0.38
Graphical presentation of the data, that is, log-probability plots
of cumulative precent less than stated micron size versus the Dpc for
each stage in microns, is included in this appendix. A graphically determined
mass median diameter (HMD) and geometric standard deviation ( 0g) for each
sample are presented in the following Table 1.
* Industrial Engineering and Chemistry, Vol. 50, April 1958, pp 645-648
J-l
-------�
TABLE 1
DATE
8/31/71
"
n
9/1/71
n
"
n
n
"
n
u
9/2/71
it
n
n
n
n
u
SAMPLE
NO.
1
2
3
4
5
6
. 7
8
10
9
11
12
13
14
15
16
17
18
LOCATION OF
SAMPLE
BAGHOUSE EXHAUST
n M
n n
M n
it it
ii n
FURNACE EXHAUST
n ii
n n
n n
n u
BAGHOUSE EXHAUST
it n
n M
FURNACE EXHAUST
it n
n M
n n
PORT
NO.
SE
CE
NE
n
CE
SE
B
C
B
B
C
SE
CE
KE
C
B
B
C
DURATION OF
SAMPLE
(MINUTES)
120
n
ti
180
ii
it
5
n
n
11
n
240
n
il
5
n
.Ml
"
AP ACROSS
IMPACTOR MMD
(IN. Hg) (y)
5 1.50
1.26
» *.
10 0.74
0.86
" 0.48
5 0.62
11 3.20
1.01
11 0.79
11 0.26
10 **
" 0.83
u 0.84
5 0.30
0.59
1.30
0.73
og
(y)
2.26
2.38
*
3.91
2.80
7.10
3.42
4.85
3.86
3.79
3.81
*
2.17
3.06
8.47
3.59
5.51
7.70
REMARKS
Sampled between taps
Sampled simultaneously
between taps
Sampled simultaneously
during tap
Simultaneous samples
Sampled simultaneously
during tap
Sampled simultaneously
between taps
* AN INSUFFICIENT QUANTITY OF PARTICLES DEPOSITED ON THE COLLECTOR PLATES
TO DETERMINE MMD AND og
KJ
-------�
SUB-APPENDIX J.-l
GRAPHICAL PRESENTATION OF RESULTS
J-3
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
30 40 50 60
o
00
I
•x
EPIGURE:: NUMBER ^in
OLLECTEIX-AT
BAGHOUSE EXHAUST;
Mill III I 1 I I I I
4.5 5.0 5.5
PROBITS
6.0
6.5
7.0
J-4
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
40 50 60
O «
CO «
O =
<0 i
(0 a
Jo 5;
mo it
3
NUMBER Z'COLLECTED
-BAGHOUS.E'-EXHAUST
J-5
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
40 50 60
CO
CtJ
u
M
SB
tA
Ss
00
8-
C.X
ae-
; Sample No.6
^i^'o^sy
iTi^tT^ fog i~"F;":3".TOM
93%
'T\
T
±^SAMPLE"'N^ERS;;^;V;:^:AND
^i>IUL5-ANEOUSLY-AT-tHE--BAGHOUSE-EXHAuST~
±itr:
.t-L:
:!irrr
IZI-TIpi—L
-u u^ L
TI
3.0
3.5
4.0
I I I i I I II I I I
4.5 5.0 5.5
PROBITS
6.0
I
7.0
J-6
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
30 40 50 60 70
LLECTED BETWEEN^FURNACE
-FURNACE:;EXHAUST -DUCT
Mill
4.5 5.0
PRORITR
6.5
7.0
J-7
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
40 ' 50 60
1
o
CO
O
co
(0
t
(ft
u
ffl (J
12
O.X
USLY-'-'BElwEN FURNCE-: TA
S 1-FURS'AGE-^EkHAUST--DUCir--
Mil i I i!
4.0 4.5
3.0
i I i I I ! I ! I I i
5.0 5.5
PROBITS
J-8
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
30 40 50 60
O <
co ^
O =
O 2
(OS
en
z
§
O
u
*
•
Drf
W
W
d
M
&
1
.9
.8
.7
.6
.5
.4
.3
.2
n Jd <
U P4
K
U
d *
t> J
du £
ou i;
23s
S«
O.X
i
NUMBERS -9- AND'"11 COLLECTED
i ! I
-U4-
L-T-.
-Ul
SIMULTANEOUSLY. jDURING:;EUpACE j TAP.:: A1
THE LFURNACE-' EXHAUST JDUCT :\r.'~..
LJ.L
3.0
I
3.5
I T I 1 1 I I I I
4.0 4.5
i I I I I i i I i i ! i I i
5.0 5.5 6.0
PROQITS
I I
I I
i I
7.0
J-9
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
40 50 60
el-
s':
o =
CO *
(0 S
O.X
IAI
o
SIMULTANEOUSLY, AT- THE)BAGHOUSE EXHAUST
3.0
i i i i r i i i M i
4.0 4.5 5.0
PROBITS
J-10
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
25
9
8
.7.
6
10 15 20
30
PERCENTAGE
40 50 60
70
80 85 90
95
I
8
2
M
O
« .3
98%
9
8
7
6
o-
8-
u PK
ax
-i i_
LU4-
,S- T 5-AMQ4-6-CQLLECTEL
lI'MiLtiNEdU^LYi-'-bURiNGt-FURN'AcEitAi
J— AT--'1
T TrrT-
HEjJlJ
-J.-
RNACii -'OUTLET DUCT i
:t:
I
n~
:p
-C:
3.0
! I
r i
4.0
I I II- I I I
4.5
I I I I I I I I I i I I I i I ! 1
5.0 5.5 6.0 6.5
PROBITS
I I I
7.0
J-ll
-------�
CUMULATIVE PERCENT LESS THAN STATED MICRON SIZE
PERCENTAGE
40 50 60
98?S
S
2
M
CJ
0« t
°"
o =
01
(0 o .
'
->- J
JU U
oo !;
S3
8-
fl.X
I i II ill M I I I i I M i Mi
4.5 5.0 5.5 6.0
PROBITS
J-12
-------�
SUB-APPENDIX J-2
FIELD DATA
J-13
-------�
PARTICLE SIZING
_ .. _._.-. Date
Stack No.,
5 3. S3Z 3 J.SJ/7
filter
3.0
(cr) "~*
/
-------�
PARTICLE SIZING
Date
Stack No. ^?,' // /
2 3. 6/93 3.1/90 0.$
(cr)
$ +3.4/73 2. 22»3
filter 0./Z0*/
'AX^
J-15
-------�
PARTICLE SIZING
Date
Stack No.,
No.
Cum. %
Stage Post Wt. Pre Tft. Wt Gain % less than Doc
3 3,1399
filter £>,/2?/
0.7
J-/UAJL
A/07 £*/46>6/) £>#?/?
*?
S.o
/9.78
2./.8Z
zt/.&z, . s.o
26, SO S-O
= 2&./O <2-«"
J-16
-------�
PARTICLE SIZING
Stack No
r
Sample No.
Stage Post Tffc. Pre Wt.
J. 633?
Wt Gain
%
Cum. £
less than Doc
5 J.S32.S
filter a. ^ 7 J
6,7
7*7/?
J-17
-------�
PARTICLE SIZING
Date
Stack No.
Sample No.
//2S"
filter 6.
3/.8a
C>9'8
6.2.
/,
Cum. %
e Post Wt. Pre Wt. Wt Gain % less than Doc
, 7
/
j-18
-------�
Stack No.
PARTICLE SIZING
Dfcte 9-S-?/
Sample No.
Cum. %
Staee Post Wt. Pre Tft. Wt Gain % less than Doc
filter
//<*> /
-38.&G
/a, a
'. 2 <* ^^ ' ° •V7i z-3 ^ •*•** ^^ ' • ' *" J~^9
-------�
Stack No.
PARTICLE SIZING
Ikte 9-S-7/
Sample No . ~7
filter 9*£
J-20
-------�
PARTICLE SIZING
Stack No.
Smmpla No.
State Post Tft. Pre Wt. Wt Gain
J. SV73
Cum. %
less than Doc
S2.Q
2 J. 4,2. oo
(,,&
3 3.
3. S79S
/2,3
3.
7-7
filter 0.
7-7
//
J-21
-------�
PARTICLE SIZING
Stack No .
Date P-/-/V
Sample No.
Staee Post Wt. Pre Tft.
1 3.
Wt Gain
3.S9/V
%
Cum. %
less than Doc
2 3.36X7
3.3 £3 1>
2.J
/0.Z.
77.
3.S933
.7
2.7
5 3.2.9Z&
filter
/7Z2
-S7'**?'
714 . //
J-22
-------�
Stack No.
PARTICLE SIZING
Date .9-/-7V
Sample No.
Cum. %
Stare Post Wt. Pre Tft. Wt Gain $ less than Doc
3- ^/£ Z.
-------�
PARTICLE SIZING
Stack Wo *
Date 9-S-7/
Sample No. / /
State Post T-ft. Pre Vb. Wt Gain
Cum. $
less than Doc
Z.-z.
. ^5 7Z.
/A
filter d.
/7Z2
7- <-/
. 9
J-24
-------�
PARTICLE SIZING
Date
Stack No.
3.Z
filter
90.80
/as?
3.6/93
& ?e> 9 <$S,6
-------�
PARTICLE SIZING
Stack No. C£
Sample No. /3
Date 9-a-
Stage Post Wt. Pre Vt.
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PARTICLE SIZING
Date 9-2-7 S
Stack No. //£"
Sample No. /V
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PARTICLE SIZING
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J-28
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PARTICLE SIZING
Stack No. Pb^T & ,
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Cum. %
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Stack No.
PARTICLE SIZING
Date
Sample No. /?
Cum. %
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5 3.
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PARTICLE SIZING
Stack No.
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APPENDIX K
CHEMICAL ANALYSIS OF EMISSIONS
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4742.3.71-152
CHEMICAL ANALYSES OF EMISSIONS
FROM
REACTIVE METALS SMELTING OPERATIONS
1. INTRODUCTION
Particulate fumes and gaseous emissions are generated during the process-
ing of a commercially important class of ferroalloy materials called reactive
metals. The particulate portion of these emissions is collected on glass
fiber filters strategically placed in the air stream of a ventilation system.
Six such filters from Airco (Niagara Falls, New York) were analyzed by atomic
absorption and qualitative electron beam X-ray microanalysis. Each of the six
filters prior to compositing was examined microscopically.
2. TEST RESULTS
2.1 Optical Examination
The loaded filters were examined at magnifications up to 30X. Under
tungsten filament illumination the separate filters appeared as follows:
ABD-1M Dark gray powder with black particles-no quartz
fibers from the collector pad visible.
ABD-2M Light gray powder with very few black particles-
no quartz fibers from the collector pad visible.
ABD-3M Dark gray powder with black particles-quartz fibers
from the collector pad visible.
ANE-1M Light gray powder with black particles-quartz fibers
from the collector pad visible.
ACE-1M A few black particles among the quartz fibers.
ASE-1M A few black particles among the quartz fibers.
K-l
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4742.3.71-152
Page 2
The optical examination revealed that:
1. Four filters had trapped a heterogeneous particulate material
consisting predominantly of a gray powder and a minor amount
of black particles.
2. The amount of sample collected in four cases was so small that
the fibers from the filters could still be seen. In fact, in
two such samples, only a small amount of the black particles
could be seen against a background that was predominantly the
filter material.
Two different techniques were necessary to form composite samples:
1. Simple Blending of Loose Powders
Samples ABD-1M, ABD-2M, and ABD-3M were shaken, lightly scraped
and copious amounts of loose gray material were gathered, blended,
and designated as Niagara Falls Airco Inlet Duct Sample ABD-M. A
negligible amount of the collector filter material was included
in the blended sample.
2. Dissolution in a Common Reagent
Samples ANE-1M, ACE-1M, and ASE-1M were submerged (particulate
matter and filter pads) in a common solution of sulfuric acid.
A control experiment was also run on a unused filter pad to
determine the contributions of the filter. The composited sam-
ple in this case was labeled Niagara Falls Airco Stack Sample
ABE-M.
Small samples for electron beam X-ray microanalysis were cut
from every specimen prior to formation of any composite samples.
K-2
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4742.3.71-152
Page 3
2.2 Electron Beam X-Ray Mi preanalysis
The electron microprobe is an advanced piece of equipment which uses a
small beam of electrons to produce characteristic X-ray emissions from a sam-
ple volume with a radius of ~1 micron. Curved crystal X-ray spectrometers
are used to analyze the resultant characteristic X-ray spectra. An examina-
tion was made of the complex spectrum of X-rays given off by the specimen
under electron beam excitation, and it was found that the entire spectrum
could be identified uniquely. All portions of the X-ray spectrum in the
wavelength range 1-100A covering all elements except H, He, Li, and Be were
taken into account.
In these analyses, the electron beam was defocused to a diameter of ~150
microns (0.006 inch) to cover a relatively large area of the specimen and to
insure that both the gray condensate and the black particles were analyzed.
The electron beam impinged in vacuum on the untouched surfaces of three specimens:
1. Sample ABD-1M
In this sample, the layer of particulate material was far too
thick to allow penetration of the electron beam into the
collector (filter) pad. In other words, only the condensed
particulate material was analyzed in this case.
2. Sample ABD-3M
The layer of particulate was sufficiently thin that a contri-
bution from the collector pad may be present.
3. Sample ANE-1M
A contribution from the collector was definitely present in
this case because the fibers from the collector could be seen
in the optical microscope viewing system attached to the
electron microprobe.
The qualitative results are compiled in Table 1 and provide the basis for
selection of elements for quantitative analyses. Note that a total of 15 ele-
ments were found* and that the stack sample (ANE-1M contained a small but
distinct amount of both sulfur and chlorine. Special mention is made of these
*
. The spectral scans were conducted in a manner such that all elements except
H, He, Li, Be, B, N could be detected.
K-3
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Table 1. Qualitative Electron Beam X-Ray Microanalyses
Specimen
Ho.
ABD-3M
ABD-2M
Airco Inlet
Duct Sample
ANE-1M
Airco Stack
Sample
Cr
M
M
T
Mn
T
T
_
Mg
H
H
H
Fe
T
T
T
Al
L'
L
M
Ca
T
T
H
Ba
-
_
L
Na
T
r
M
K
M
L
M
Zn
T
T
T
Cl
-
_
T
S
-
_
T
Si
H
H
H
0
H
H
H
C
L
L
L
KEY: H =
M =
L =
T =
greater than 20 wt%
10-20 wt%
1-10 wt%
less than 1 wt%
rc ro
-Pi CO
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I
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ro
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4742.3.71-152
Page 5
elements because they were not included in the quantitative analyses which will
be described in the next paragraph. Note also that oxygen was detected at
about the 50%, thereby suggesting that the particulate material was a mixture
of oxides.
2.3 Atomic Absorption Analyses
Atomic Absorption (A.A.) means that a cloud of atoms in the un-ionized and
unexcited state is capable of absorbing radiation at wavelengths that are speci-
fic in nature and characteristic of the element in consideration. The atomic
absorption spectrophotometer used in these analyses consists of a series of
lamps which emit the'spectra of the elements determined, a gas burner to pro-
duce an atomic vapor of the sample, a monochromator to isolate the wavelengths
of interest, a detector to monitor the change of absorption due to the speci-
men, and a readout meter to visualize this change in absorption.
As stated previously, the two sets of samples were composited two differ-
ent ways for the atomic absorption analyses. The detailed procedures for the
physically blended powders are as follows:
1. The particulate material from three specimens was either shaken
loose or scraped from the filter pads with a wood tongue de-
presser and blended in a polyethylene container.
2. Duplicate portions of the blended powder were digested in hot
HCl-HNOo.* After cooling, the suspension was filtered.
3. The filtrate (soluble portion) was analyzed for the elements-of-
interest by atomic absorption. The precipitate (non-soluble por-
tion) was analyzed by "large beam" electron microprobe analysis and
flame photometry and found to be free of sodium or potassium. This
action was done because potassium acid sulfate (KHSO.) v/as used in
the next step.
4. The precipitate was blended with a known quantity of KHS04 and ignited
in a 850°C muffle furnace to form a fused mass which subsequently was
dissolved in HC1. Solution was not complete, and a filtra'tion step was
needed to separate the solution from a precipitate.
5. The solution was analyzed for the elements of interest by atomic
absorption, and the results from this step were added to those from
Step 3 to yield the total percentage of each element in the parti-
culate sample.
. The hot solution used was 8 ml concentrated HC1, 32 ml concentrated HN03
and 40 ml distilled water.
K-5
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4742.3.71-152
Page 6
6. . The precipitate from Step 4 v/as checked for SiO? by a gas
evolution technique.* This technique selectively decomposes
and volatilizes Si02 through reaction with hot H2S04, HN03
and HF in a platinum crucible. The portion of the sample
that still remained after all these steps was labeled an
insoluble residue in Table 2.
A different procedure was needed for those samples in which the quantity
of condensable particulate was insufficient for a physical separation. In
this case the following procedure was used:
1. Three entire collector pads, with material in and on them,
were digested in a common hot H2S04 solution. An unused
collector pad was submerged in a second identical solution.
2. The steps described previously were followed for both the
unknown and the unused sample. The results for the latter
were corrected to account for the fact that three used pads
were used with the unknown samples but only one unused pad
was employed as a blank.
3. The concentrations of elements in the condensable particulate
material was obtained by subtracting the results for the
"blank" from the total.
The results of" the atomic absorption analyses are compiled in Table 2.
The following are observations.
1. Both samples are predominantly silicon dioxide, Si02- This
conclusion is directly seen in the results for the Inlet Duct
Sample where 76.4% of the material is Si02- The concentrations
of the remaining elements are all low in comparison, and magnesium
is the highest at an average 5.44% level. The sum of all the
percentage values is 100%, and this indicates excellent closure
(mass balance). The 100% value is achieved when all the metal
percent values are converted to their equivalent oxide percent
values.**
N. H. Furman, Editor, Standard Methods of Chemical Analysis, 6th Edition,
Volume 1, D. Van Nostrand Company, Princeton, N. J., p. 950.
Equivalent oxide percentages are obtained by multiplying the weight percent
metal in Table 2 by the ratio. Mo/Mm where Mo is the molecular weight of the
metal oxide and Mm is that of the metal.
K-6
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Table 2. Elemental Analysis of Particulate Matter
Sample
ABE-M
Airco Stack
Sample
ABD-M
Airco Inlet
Duct Sample
Element wt%
Na
12.7
0.23
0.22
K
0.9
0.25
0.25
Mn
0.1
0.054
0.050
Fe
1.0
0.10
0.08
Zn
0.6
0.32
0.37
Cr
<.4
«
0.46
0.42
Ca
4.0
0.59
0.27
Mg
0.6
5.28
5.59
Al
8.0
0.38
0.35
Ba
<4.
<.4
Ti
<8.
<.8
Si02
(a)
76.8
76.0
Insoluble
Residue
(b)
—
11.5
13.2
(a) No Si02 quantitative results were determined for this sample which was a composite of three filters
and their condensable particulate samples. The sample was known in advance to be predominantely SiOp-
(b) The residue that seemed to defy attempts at dissolution was analyzed on the electron beam X-ray micro-
analyzer and found to be primarily (~50%) platinum (from the platinum crucibles used) with lesser
amounts of aluminum, sodium, and fluorine. The latter group of elements probably are evidence
of incomplete digestion in the hot acid steps conducted early in the analysis-separation
scheme.
T3 I"**1
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4742.3.71-152
Page 8
2. The Stack Sample, in comparison with the Inlet Duct Sample, con-
tains relatively more of every metal cation except magnesium.
The absolute amount of 'the Stack Sample v/as far less and this
had an impact on the sensitivity values. Thus the lower limits
for barium and titanium are 4% and 8% in the Stack Sample (rather
than 0.4 and 0.8%) because the total sample mass was limited to
"11 milligrams.
3. It must be emphasized that the values have been corrected to
account for the contributions from the filter pads. In other
words, the 12.7% Ma value is for the particulate matter collected
on a filter and ncrt for the filter pad.
K-8
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