RTI/2218/35-01
STATUS REPORT #4
STABILITY OF ORGANIC AUDIT MATERIALS
AND RESULTS OF SOURCE TEST ANALYSIS AUDITS
R. K. M. Jayanty
W. F. Gutknecht
C. E. Decker
EPA Project Officers:
EPA Contract No.:
Joseph E. Knoll
Darryl J. von Lehmden
68-02-3431
Prepared for
U.S. Environmental Protection Agency
Environmental Monitoring Systems Laboratory
Quality Assurance Division
Research Triangle Park, North Carolina 27711
June 1982
RESEARCH TRIANGLE PARK, NORTH CAROLINA 27709
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TABLE OF CONTENTS
SECTION NO. PAGE
1.0 INTRODUCTION 1
1.1 Objectives 1
1.2 Audit Materials Contained in the Repository ... 1
2.0 EXPERIMENTAL PROCEDURES 5
2.1 Instrumentation 5
2.2 Calibration 5
3.0 PERFORMANCE AUDITS 8
4.0 STABILITY STUDIES. 19
5.0 SUMMARY AND CONCLUSIONS 21
REFERENCES 22
ATTACHMENT 1 - STABILITY DATA AS OF MAY 1982 23
ATTACHMENT 2 - SAMPLE CALCULATIONS OF PERCENT CHANGE/MONTH . . 70
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SECTION 1.0
INTRODUCTION
1.1 OBJECTIVES
The need for reliable standards for source emission measurement of
hydrocarbons, halocarbons and sulfur compounds is well established.
The Research Triangle Institute (RTI) under contract to the U.S.
Environmental Protection Agency (USEPA) has responded to this need
through development of an extensive repository of gaseous compounds.
The main objectives of this ongoing project are (1) to provide gas
mixtures to EPA, state/local agencies, or their contractors, as
performance audits to assess the relative accuracy of source emission
measurements in certain organic chemical manufacturing industries, (2)
to corroborate the vendor's certified analysis of the gas mixtures by
in-house analysis, (3) to determine the stability of the gas mixtures
with time by in-house analysis, and (4) to explore the feasibility of
new audit materials as requested by EPA.
This report describes the present status of this project. Includ-
ed in the report are (1) a description of the experimental procedures
used for initial cylinder analyses and collection of stabilty data, (2)
a description of the audit procedure, (3) presently available audit
results, and (4) presently available stability data. Full details of
the study with additional statistical analysis will be presented in the
final report and also in a journal publication.
1.2 AUDIT MATERIALS CONTAINED IN THE REPOSITORY
The RTI repository currently contains 40 different compounds for
use in conducting performance audits during source testing. The
compounds were selected based on the anticipated needs of the personnel
of the Emissions Measurements Branch, Office of Air Quality Planning
and Standards, USEPA. Table 1 lists the compounds, the concentration
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ranges, the number of cylinders of each compound, and the cylinder
construction material. In Table 1, the audit materials fall into two
concentration ranges. The low concentration range between 5 and 20
parts per million (ppm) simulates' possible emission standard levels.
The high concentration range between 50 and 700 ppm simulates expected
source emission levels. The balance gas for all gas mixtures is
nitrogen. In the case of some of the audit materials, a second
compound, which serves as an internal standard, was added to the gas
mixture.
2
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TABLE 1. AJDIT MATERIALS CLRRENTLY HELD IN THE REPOSITORY
Lew Concentration Range High Concentration Range
Canpomd No. of Concentration Cylinder No. of Concentration Cylinder
Cylinders Range (ppni) Construction* Cylinders Range (ppn) Construction*
Benzene
14
8 - 13
S
17
60 - 400
Al
Ethylene
4
5 - 20
A1
4
300 - 700
Al
6
3000 - 20,000
Al
Propylene
4
5 - 20
A1
4
300 - 700
Al
Methane/Ethane
-
-
4
1000 - 6000(M),
Al
200 - 700(E)
Propare
4
5-20
A1
4
300 - 700
Al
Toluene
2
5 - 20
S
2
300 - 700
S
Hydrogen Sulfide
4
5 - 20
A1
2
300 - 700
Al
MetohXylene
2
5 - 20
S
2
300 - 700
LS
Methyl Acetate
2
5 - 20
S
2
300 - 700
S
Chloroform
2
5 - 20
S
2
300 - 700
S
Carbonyl Sulfide
2
5 - 20
S
2
100 - 300
S
Methyl Mercaptan
4
3 - 10
Al
-
-
Hexane
2
20 - 80
A1
2
1000 - 3000
LS
1,2-Dichloroethane
4
5 - 20
Al
4
100 - 600
Al
Cy:lohexane
-
-
1
75 - 200
S
Methyl Ethyl Ketone
1
30 - 80
S
-
-
Methanol
1
30-80
Al
-
-
1,2-Dichloropropane
2
5 - 20
Al
2
300 - 700
LS
Trichloroethylene
2
5-20
Al
2
100 - 600
Al
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TABLE 1. AUDIT MATERIALS CLRRENTLY HELD IN THE REPOSITORY (Continued)
Lew Concentration Range High Concentration Range
Compound Ni. of
Cyl inders
Concentration
Range (ppm)
Cylinder*
Construct ion
to. of
Cylinders
Concentrat ion
Range (ppn)
Cylinder*
Construct ion
1,1-Dichloro-
ethylene
2
5 - 20
A1
2
100 - COO
Al
1,2-Dibrcmo-
ethylene
2
5 - 20
A1
2
100 - 600
A1
Perdiloro-
ethylene
2
5 - 20
S
2
300 - 700
LS
Vinyl Chloride
9
5-30
S
-
—
1,3-Butadiene
1
5 - 30
S
-
—
Acrylonitrile
2
5 - 20
LS
2
300 - 700
LS
Aniline
1
5 - 20
A1
-
—
Methyl Isobutyl Ketone
1
5 - 20
A1
1
50-100
Al
Cyclohexanone
2
5 - 20
A1
-
—
Par a-d ichl orobenzene
2
5 - 20
S
-
—
Ethyl anine
2
5 - 20
A1
-
—
Formaldehyde
-
—
-
-
—
Methylene Chloride
1
5 - 20
A1
-
—
Carbon Tetrachloride
1
5 - 2D
A1
-
—
Freon 113
1
5-20
A1
-
—
Methyl Chloroform
1
5 -20
A1
-
—
Ethylene Oxide
1
5 -20
A1
-
—
Propylene Oxide
1
5 - 20
A1
1
75 - 200
Al
Allyl Chloride
1
5 - 20
S
1
75 - 200
S
Acrolein
1
5 - 20
A1
1
75 - 200
Al
fUl
Isll IW* UJO I/.OIC
i
X
C _ Tfl
*J l_vy
Al
-
—
Carbon Disulfide
-
—
A1
-
75 - 200
Al
*Cylinder construction: A1 - Aluninun, S - Steel, LS - Lew Pressure Steel
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SECTION 2.0
EXPERIMENTAL PROCEDURES
Analysis of the cylinder gases is required to corroborate the
concentrations reported by the company which prepared the gas mixtures
and also to measure concentration changes with time, that is, estimate
stability of the standards.
2.1 INSTRUMENTATION
Analyses are performed with (1) a Perkin-Elmer Model 3920B Gas
Chromatograph with flame ionization and flame photometric detectors,
and (2) a Tracor Model 560 Gas Chromatograph with a flame photometric
detector. The Tracor instrument has been used principally for
measurement of the sulfur-containing species. The gaseous samples are
injected onto the columns by means of gas sampling valves constructed
of Hastalloy C (high nickel content and low adsorptive properties).
These valves are equipped with interchangeable sample loops to allow
the injection of variable but known volumes of gas. To further
facilitate the injection of varying sample sizes, a sample injection
system (Figure 1) is employed. The operation of the system is based
upon measurement of pressure differentials. Further details on the
system are published in the open literature (1).
The gas chromatographic parameters used in the measurement of
individual compounds and problems that have arisen are listed in
Attachment 1.
2.2 CALIBRATION
Calibration of the gas chromatographs has involved measurement of
known concentrations of gases in air or nitrogen. The source or method
of preparation of calibration standards varies depending on the gas
involved.
National Bureau of Standards, Standard Reference Materials
(NBS-SRM's) of methane and propane are used for the calibration of the
GC for the measurement of methane and propane audit materials. These
5
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HELIUM
O
VALCO HASTALLOY-C _nl.
VALVE \ T0 GC
A/ ~
\
O
SAMPLE
GAS
BOTTLE
TEFLON
VALVE
C
r
1
3
HEISE VACUUM
- PRESSURE GAUGE
NUPRO STAINLESS
STEEL TOGGLE VALVES
Q
VACUUM PUMP
Figure 1. Sample Injection system.
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same gases are used to calibrate the chromatographic system for
measurement of ethylene and propylene, assuming the FID response per
carbon is constant from compound to compound.
A second method for the quantitation of gaseous compounds involves
the use of permeation tubes. Thus, the calibration gases for vinyl
chloride and ethylene oxide have been generated using permeation tubes.
The tube is placed in a temperature-controlled chamber and zero air is
passed over the tube at a known flow rate. The resultant gaseous
mixture is further diluted if necessary with additional zero air in a
glass dilution bulb. The final mixture is collected in a gas sampling
bulb or a Tedlar® bag and analyzed by GC-FID. The permeation rates of
the tubes are determined periodically by weight loss.
A third method for developing a standard is the "glass bulb"
technique. A known volume of the compound, either gas or liquid, is
injected into an evacuated glass bulb of known volume. The bulb is
then returned to atmospheric pressure with a balance gas of choice. If
a pure liquid is injected, total vaporization is assumed and the
concentration is calculated by using the ideal gas law. Additional
dilutions are also made, if necessary, by utilizing additional bulbs or
by repeatedly pressurizing with a balance gas to a known pressure and
then partially evacuating to a known pressure.
With each of these approaches, multipoint calibration curves are
prepared each time a sample is analyzed. Certain quality control
procedures are followed, for example, equilibrating the permeation
system and the glass bulbs with the sample gas before taking an aliquot
for GC measurement. Also, an NBS standard cylinder of methane is used
to verify the constancy of the detector response. Blank measurements
are taken during the process of cylinder analysis and generally, blank
measurements have shown no signal above the baseline.
7
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SECTION 3.0
PERFORMANCE AUDITS
RTI supplies repository cylinders for audits upon request from
EPA, state or local agency or a contractor. The contractor must be
performing source emission tests at the request of EPA, state or local
agency in order to qualify for the performance audit. When a request
is received, the contents of the cylinders are analyzed, the tank
pressures are measured and the cylinders are shipped by overland
carrier. Tank regulators are also provided when requested. A letter
is included with the cylinders which provides general instructions for
performance of the audit. The audit concentrations and cylinder
pressures are provided to the requesting agency audit coordinator.
To date, 86 individual audits have been initiated, and 83 are
complete. The audit results collected to date are presented in Table
2. Generally, the results of the audits show close agreement (+^ 10%)
with the actual cylinder concentrations measured prior to shipment.
8
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TABLE 2. SUMWRY OF PERFORMANCE AUDIT RESULTS
Audit RTI audit Client audit Status of
No. CI ient Industry Audit material conc. (ppm) % bias (Avg.) audit
1
A
Ethylene oxide
product ion
Ethylene in N2
Ethylene in N2
3,239
21,226
-22.5
-20.0
E
2
A
Ethylene oxide
production
Methane/ethane in N2
Methane/ethane in N2
l,710Me/220Et
8,13CMe/597Et
+9.00/-20.0
+9.00/-1.00
E
3
A
Ethylene oxide
production
Methane/ethane in N2
Methane/ethane in N2
l,021Me/315Et
6,207Me/773Et
+21.5/-4.50
+23.5/-4.50
E
4
A
Acetone
product ion
Benzene in ^
Benzene in N2
79.0
374.0
-19.0
-11.0
E
5
A
Maleic anhydride
production
Benzene in N2
Benzene in N2
138
300
-9.40
+4.70
E
6
A
Ethylene oxide
production
Ethylene in N2
Ethylene in N2
5,442
18,918
-27.0
-33.0
E
7
B
Maleic anhydride
production
Benzene in N2
Benzene in N2
80.0
355
+2.30
+27.5
E
8
C
Maleic anhydride
production
Benzene in N2
Benzene in N2
101
387
+12.9
+14.5
E
9
D
Ethyl benzene
styrene
manufacturer
Benzene in N2
Benzene in N2
71.0
229
-2.80
-3.90
E
10
E
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
62.0
80.0
+3.80
+3.40
E
11
F
Gasoline transfer Benzene in N2
terminal Benzene in N2
142
294
-3.50
+3.20
E
12
F
Gasoline transfer Benzene in N2
terminal Benzene in N2
268
343
-11.8
-1.00
E
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TABLE 2. SUfWRY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit
No.
Client
Industry
Audit material
RTI Audit
conc. (ppm)
Client Audit
% bias (Avg.)
Status of
audit
13
F
Gasoline transfer Benzene in N2
terminal Benzene in N£
129
318
I
1
O O
T?
E
14
F
Gasoline transfer Benzene in N2
terminal
10.7
+2.60
E
15
C
Nitrobenzene
manufacturing
Benzene in No
Benzene in N^
9.73
269
-4.60
-2.60
E
16
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
8.20
140
-2.30
-1.80
E
17a
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
9.50
127
+10.4
-2.80
E
17b
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
9.50
127
+12.5
-6.30
E
18
Coke a/en
Hydrogen sulfide in
Hydrogen sulfide in
n2
n2
7.05
9.73
-24.8
-22.9
E
19
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
12.0
218
-0.80
+7.30
E
20
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
7.65
396
+16.3
+1.50
E
21
F
Linear alkyl-
benzene manu-
facturing
Benzene in N2
Benzene in N2
Benzene in N2
98
294
331
+5.70
+6.80
+4.50
E
22
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
9.85
81.0
-4.10
-6.80
E
23
F
Gasoline bulk
terminal
Benzene in N2
Benzene in N2
10.2
61.0
+4.60
-9.50
E
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TABLE 2. SUMQRY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit RTI audit Client audit Status of
No. Client Industry Audit material cone, (ppm) % bias (Avg.) audit
24
H
Industrial
surface coating
process
To 1 iene in N2
Propylene in N2
Propane in N2
Methane/ethane in N2
14.8
474
20.3
l,640Me/195et
-1.90
+0.20
-2.30
-13.5(as methane)
E
25
C
Acrylic acid and
ester Production
Propane in N2
Propane in N2
10.1
710
+8.60
+5.60
E
26
C
Acrylic acid and
ester Production
Propane in N2
Propane in N2
5.10
607
+-17.6
-3.60
E
27
E
Maleic anhydride
Benzene in N2
Benzene in
10.2
218
NA
m
F
28A
A
Carbon adsorber
Toluene in N2
Toluene in N2
8.55
405
-6.40
-1.00
E
288
A
Carbon adsorber
Toluene in N2
Toluene in N2
8.55
405
+4.10
NA
E
28C
A
Carbon adsorber
Toluene in N2
Toluene in N2
8.55
405
-8.80
m
E
29
EPA, QAD
Instrunent
check-out
Ethylene in N2
Ethylene in N2
Ethylene in N^
Ethylene in N2
Ethylene in n£
4.75
19.6
312
3021
20456
+4.00
+3.10
-0.80
+5.30
-8.60
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TABLE 2. SUfWRY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit kll Audit Client Audit Static of
No. Client Industry Audit material conc. (ppm) % bias (Avg.) audit
30
EPA,
QAD
Instrunent
check-out
Benzene in ^
Benzene in N2
Benzene in N2
Benzene in N2
8.20
78.0
133
348
-K).30
-0.90
-4.00
-0.90
E
31
EPA,
QAD
Instrunent
check-out
Toluene in
Toluene in N£
405
579
+3.20
+1.00
E
32
EPA,
QflD
Instrunent
check-out
Methyl acetate in N
Methyl acetate in N
Methyl acetate in N
Methyl acetate in N
6.80
17.2
326
455
-2.60
+1.70
-1.50
-1.30
E
33
EPA,
QAD
Instrunent
check-out
Propylene in N2
Propylene in N2
Propylene in N2
Propylene in N2
4.90
19.7
300
685
-22.4
-7.80
+1.00
-1.80
E
34
EPA,
QAD
Instrunent
check-out
Propane in ^
Propane in N2
Propane in N2
14.6
303
439
-0.70
+7.60
+6.20
E
35a
I
Vegetable oil
pi ant
Hexane in N2
Hexaie in N2
82.2
1982
+8.10
+3.00
E
35b
I
Vegetable oil
plant
Hexane in N2
Hexane in N2
82.2
1982
-1.20
-1.30
E
36
A
Carbon adsorber
Toluene in No
8.20
-2.40
E
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TABLE 2. SUMQRY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit RTI audit Client audit Status of
No. Client Industry Audit material conc. (ppm) % bias (Avg.) audit
37
B
Coke a/en
Benzene in N2
Benzene in N2
12.1
105
¦•0.80
+2.90
E
38
D
Ethylbenzene/
styrene
Benzene in N2
Benzene in N2
Benzene in N2
9.90
77.9
345
+5.70
+3.60
+1.50
E
39
B
Coke a/ en
Byproduct
Benzene in N2
Benzene in N2
8.20
85.4
-2.60
-8.70
E
40
D
Coke even
Byproduct
Benzene in N2
Benzene in N2
10.9
147
+20.0
+6.80
41
H
Paint spray
Benzene in N2
m-Xylene in N2
10.8
15.4
NA
m
F
42
H
Tire
manufacturing
Cyclohexane in N2
93.4
-11.1
D
43
B
Coke o/en
Benzene in N2
Benzene in N2
7.54
225
+0.10
+0.40
D
44
D
Ethyl benzene/
styrene
Benzene in N2
Benzene in N2
Propane in N2
8.20
74.5
10.6
-3.40
-0.20
-3.00
D
45
F
Industrial
sir face coating
Propane in Air
Propane in Air
316
450
-3.20
-2.00
E
46
EPA, QAD
Tire
manufacturing
Propane in Air
Propane in Air
15
316
m
m
F
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TABLE 2. SUWWRY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit
No.
Client
Industry
Audit material
RTI audit
conc. (ppm)
Client audit
% bias (Avg.)*
Status of
audit**
47
EPA, QAD
Tire
manufacturing
Propane in air
Propane in air
20.8
453
-18.4
+13.4
E
48
D
Dimethyl
terephthal ate
production
Meta-Xylene in air
487
-2.10
E
49
EPA, QAD
Instrunent
check-out
Toluene in N2
Methanol in N2
61.5
55.2
m
F
50
EPA, QAD
Tire oven
manufacturing
Propane in air
Propane in air
Propane in air
4.90
613
718
-48.8
+16.9
+16.8
E
51
EPA, QAD
Instrument
check-out
Propane in air
Propane in air
20.8
316
+20.0
-9.20
E
52
D
Styrene
manufacturing
Benzene in N2
Benzene in
1,3-Butadiene. in N2
106
358
20.9
-4.90
-3.70
+23.8
E
53
I
Veg. oil
manufacturing
Cyclohexane in N£
99.0
-3.50
E
54
M
Research
Chloroform in N2
Chloroform in N£
16.5
531
NA
NA
F
55
J
Ethylene in ^
300
+1.40
E
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No.
Client
TABLE 2. SUMWRY OF PERFORWCE AUDIT RESULTS (Continued)
RTI audit Client audit Status of
Industry Audit material conc. (ppm) % bias (Avg.)* audit**
56
57
58
59
EPA, QAD
Reactivity of
vent activated
charcoal
Instrunent
check-out
Coil coating
Chloroform in No
Hydrogen sulfide
in N2
Propane in N2
Propane in
Benzene in N2
Benzene in No
8.11
16.2
5.20
472
9.45
341
m
m
m
-8.40
M
m
60 M
61 EPA (State of Conn.)
62 0
63
64
M
Audit not initiated
Benzene in N2
Meta-xylene in N2
Hexaie in N2
Methyl mercaptan
in N2
Benzene in N2
Methyl ethyl ketone
in No
B3
760
1986
4.44
13.4
44.5
W
m
m
w
m
F
F
F
F
65
Coke even
Byproduct
Recovery
Benzene in N2
Benzene in N2
7.93
132
-2.90
+1.39
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Audit
No.
TABLE 2. SUMWRY OF PERFORMANCE AUDIT RESULTS (Continued)
RTI audit
Client
Industry
Audit material
conc.
Client audit Status of
(ppni) %bias(Avg.)* audit**
66
67
68
69
70
71
72
73
EPA, Region II
EPA, QAD
EPA, Region I
E
EPA, QAD
EPA, QAD
Ribber
manufactir ing
Coke even
Byproduct
Recovery
Instrunent
Check-out
Degreasing
vent
Instrument
check-out
Canbustion
efficiency
test
Benzene in N2
Benzene in 1^
Benzene in
Benzene in
Hexane in N2
Hexane in N2
Propane in N2
Propane in
Benzene in N2
Benzene in N2
Vinyl chloride in N2
Vinyl chloride in
Propylene in N2
Propylene in
Vinyl chloride in N2
Trichloroethylene in N2
Trichloroethylene in N2
Hexane in N2
Hydrogen sulfide in N2
Methyl mercaptan in N2
12.0
10.2
100
335
79.8
3076
9.97
314
8.29
75.7
5.74
28.3
328
725
7.5
14.9
566
3076
16.2
8.22
+14.2
0
->6.40
+6.00
+1.80
-7.50
-3.20
-10.8
-2.20
-2.50
NA
m
-7.00
-8.30
m
-0.40
-8.70
NA
-7.50
-8.90
F
E
-------�
TABLE 2. SUWARY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit RTI audit Client audit Status of
No. Client Industry Audit material conc. (ppm) % bias (Avg.)* audit*"*
74
E
Vinyl chloride
manufacturing
1,2-Dichloroethane in N2
1,2-Dichloroethane in N2
9.30
462
46.00
+3.70
E
75
N
Propane in air
Propane in air
10.0
309
m
m
F
76
F
Propane in air
Propane in air
10.0
309
m
m
F
77
D
Maleic
anhydride
Benzene in Np
Benzene in
9.46
66.9
-6.60
-11.7
E
78
EPA, Region VII
Benzene in N?
Hexane in N2
120
30.2
m
NA
F
79
D
Maleic
anhydride
Benzene in N2
Benzene in
9.46
128
-4.60
+12.5
E
80
F
Plywood/veneer
drying
Propylene in N2
Propylene in N
Toluene in N2
14.8
328
430
-4.70
+4.40
-0.80
E
81
P
Pl,ywood/veneer
drying
Propylene in N2
Propylene in N2
Toluene in
20.3
479
487
+18.2
-22.5
+32.5
E
82
J
Polypropylene
manufacturing
Propylene in N?
Propane in N2
Propane in N2
9.63
19.70
296
-0.35
¦+0.84
+0.45
E
83
I
Coke even
Hydrogen sulfide in N2
Hydrogen sulfide in N~
Carbonyl sulfide
428
647
101
+4.90
-16.54
+1.98
E
-------�
TABLE 2. SUNMARY OF PERFORMANCE AUDIT RESULTS (Continued)
Audit
No.
Client
Industry
Audit material
RTI audit
conc. (ppm)
Client audit
% bias (Avg.)*
Status of
audit**
M
J
Compliance
testing
Benzene in N£
Hexane in N?
Toluene in Ng
Methyl mercaptain in N2
7.45
72.6
15.0
5.40
+3.70
A
85
I
Steel
manufactir ing
Hydrogen sulfide in N2
Carbonyl sulfide in N2
647
9.08
+8.50
+1.00
E
86
I
Oil shale
Hydrogen sulfide in N2
Carbonyl sulfide in N2
Methyl mercaptan in N2
437
117
8.42
A
NA = Not analyzed
1m Client-Measured Concentration - RTI-Measured Concentration
*Client%Bias = RTI-Measured Concentration
**Status Codes:
A = Cylinder shipped; audit results not >et received;
B = Audit results received;
C = Audit report sitmitted to EPA;
D = Audit results received, audit report sifcmitted to EPA, cylinder not jet retirned by client;
E = Audit complete;
F = Audit completed without analysis of audit materials by client.
1977 - Audits 1-8
1978 - Audits 9-28
1979 - Audits 29-49
1980 - Audits 50-75
1981 - Audits 76-82
1982 - Audits 83-86
-------�
SECTION 4.0
STABILITY STUDIES
An ideal calibration standard or audit material should be stable
over its total time of usage. Any change or instability should be less
than the measurement error tolerated during its use. The stabilities
of the compounds in the repository are being estimated through periodic
analysis of the cylinder contents. Improved estimates of stabilities
could be determined by increasing considerably the frequency of the
analyses, however, this increase is beyond the scope and financial
limits of this project. The primary objective of this project is to
conduct performance audits during source testing to assess the relative
accuracy of the analytical results.
In this project, the gas mixtures in the repository are initially
analyzed upon receipt from the specialty gas vendor to corroborate the
vendor's analysis. If the RTI analysis differs from the vendor's value
by more than 10 percent, the cylinder is given to a third party for
analysis. The gas mixtures are again analyzed at 1 month, at 2 months,
and at one year following the initial analysis. These subsequent
analyses are made to determine the stability of the gas mixtures. In
some cases, analyses are not peformed on the dates specified above;
however, every attempt is made to acquire the data on this schedule.
Cylinder concentrations are also determined prior to each performance
audit, providing additional data for use in stability studies.
The estimates of stability have been calculated in terms of
percent change per month. These rates of change are calculated from a
linear regression analysis of the concentration/time data. Stability
estimates have been calculated only for cylinder contents analyzed
three or more times. Two standard deviations of percentage change per
month have been calculated only for cylinder contents analyzed four or
more times. Attachment 1 shows the concentrations and time periods on
which the calculations are based and the percent change per month for
each cylinder. Sample calculations for a 100 ppm benzene cylinder (See
1H, page 26) are given in Attachment 2.
19
-------�
As the number of analyses per cylinder increases, additional
statistical analyses will be performed. These additional statistical
analyses will include testing models other than the linear regression
model. Such models are needed especially where the change is rapid at
first but later becomes slow or nonexistent. The results will be
presented in a final report and journal publication.
Absolute accuracy of the cylinder analyses have not been
determined due to lack of NBS-SRM's as standards for most gas mixtures.
Absolute accuracy could be estimated by performing the analyses using
several different analytical methods or by having a relatively large
number of laboratories perform analyses on the same cylinders; both of
these approaches are beyond the financial limits of this project. An
examination of the data in Attachment 1 shows values for individual
cylinder analyses usually vary by less than 10 percent for 4-8 analyses
over 2-3 years. This variation indicates either a real change in
cylinder contents (i.e., instability) and/or the precision of the
measurement process. The possible sources of experimental error that
could result in apparent changes in concentrations include (1) the
variability of the analytical technique used for analysis, (2)
stability of and/or accuracy of calibration standards, and (3) the
ability to reproduce standards for which NBS SRM's do not exist. Each
of the above sources of variability impacts to some extent on the
resulting data presented in Attachment 1.
In some cases, the cylinder contents were lost after only a few
analyses. The possible reasons include leakage during storage or
shipping, misuse, multiple use in audits or initial low pressure in the
cylinder.
20
-------�
SECTION 5.0
SUMMARY AND CONCLUSIONS
Cylinder gases of hydrocarbons, halocarbons, and sulfur containing
organic species have been used successfully as audit materials to
assess the relative accuracy of gas chromatographic systems used to
measure source emissions. Absolute accuracy has not been determined
because of lack of standard reference materials; instead
interlaboratory bias has been reported for the performance audits
conducted during source testing. The inter 1aboratory bias determined
has been generally within 10 percent for both low and high
concentration gases (Table 2).
Of the 40 gaseous compounds studied or currently under study, 26
have demonstrated sufficient stability in cylinders to be used further
as audit materials. Four compounds (ethylamine, paradichlorobenzene,
cyclohexanone, and aniline) are not recommended as audit materials for
various reasons as discussed in Attachment 1. One gaseous compound
(formaldehyde) was ordered but the speciality gas manufacturer
indicated that cylinder gases of this compound could not be prepared.
Another ten compounds (carbon tetrachloride, methylene chloride, methyl
chloroform, Freon 113, ethylene oxide, propylene oxide, allyl chloride,
acrolein, chlorobenzene, and carbondisulfide) have recently been added
to the repository; the stability of these compounds remains to be
studied. As stated previously, the percent change per month values
reported in Attachment 1 are only estimates of stability. Detailed
statistical analyses which would separate statistical deviations from
true concentration changes with time are in progress and will be
presented in a final report and a journal publication.
21
-------�
REFERENCES
S. K. Gangwal and 0. E. Wagoner, "Response Correlation of Low
Molecular Weight Sulfur Compounds Using a Novel Flame Photometr
Detector", J. Chrom. Sci., 17, 196-201 (1979).
22
-------�
ATTACHMENT 1
Stabillty Study Data
as of
May 1982
1.0 BENZENE STABILITY STUDY
2.0 ETHYLENE STABILITY STUDY
3.0 PROPYLENE STABILITY STUDY
4.0 METHANE/ETHANE STABILITY STUDY
5.0 PROPANE STABILITY STUDY
6.0 TOLUENE STABILITY STUDY
7.0 HYDROGEN SULFIDE STABILITY STUDY
8.0 META-XYLENE STABILITY STUDY
9.0 METHYL ACETATE STABILITY STUDY
10.0 CHLOROFORM STABILITY STUDY
11.0 CARBONYL SULFIDE STABILITY STUDY
12.0 METHYL MERCAPTAN STABILITY STUDY
13.0 HEXANE STABILITY STUDY
14.0 1,2-DICHLOROETHANE STABILITY STUDY
15.0 CYCLOHEXANE STABILITY STUDY
16.0 METHYL ETHYL KETONE STABILITY STUDY
17.0 METHANOL STABILITY STUDY
18.0 1,2-DICHLOROPROPANE STABILITY STUDY
19.0 TRICHLOROETHYLENE STABILITY STUDY
20.0 1,1-DICHLOROETHYLENE STABILITY STUDY
21.0 1,2-DIBROMOETHYLENE STABILITY STUDY
22.0 PERCHLOROETHYLENE STABILITY STUDY
23
-------�
23.0 VINYL CHLORIDE STABILITY STUDY
24.0 1,3-BUTADIENE STABILITY STUDY
25.0 ACRYLONITRILE STABILITY STUDY
26.0 ANILINE STABILITY STUDY
27.0 METHYL ISOBUTYL KETONE STABILITY STUDY
28.0 CYCLOHEXANONE STABILITY STUDY
29.0 PARADICHLOROBENZENE STABILITY STUDY
30.0 ETHYLAMINE STABILITY STUDY
31.0 FORMALDEHYDE STABILITY STUDY
32.0 METHYLENE CHLORIDE
33.0 CARBON TETRACHLORIDE
34.0 FREON 113
35.0 METHYL CHLOROFORM
36.0 ETHYLENE OXIDE
37.0 PROPYLENE OXIDE
38.0 ALLYL CHLORIDE
39.0 ACROLEIN
40.0 CHLOROBENZENE
41.0 CARBONDISULFIDE
24
-------�
1.0 BENZENE STABILITY STUDY
Cylinder No.
1A
IB
1C
ID
IE
IF
1G
Cylinder Construction*
A1
A1
A1
A1
S
S
S
Manufacturer
ppn
65.4
324
200
117
61
71
80
Concentration
Date
7/27/77
7/27/77
7/27/77
7/27/77
2/10/78
2/10/78
2/10/78
PPn
(79.0)
(374)
(241)
(138)
(62.0)
(71.0)
(80.0)
Day
136
136
247
29
78
232
78
ppm
(74.0)
(337)
(216)
(144)
(62.0)
(73.0)
(81.0)
RTT
Day
156
156
252
157
216
385
216
Concentration
ppm
(78.0)
(350)
(215)
(134)
(61.0)
(75.0)
(81.0)
Day
167
167
381
252
385
586
385
ppm
(80.0)
(355)
(218)
(129)
(65.0)
(74.5)
(84.0)
Day
630
402
290
722
882
504
ppm
(77.9)
(331)
(127)
(66.9)
(75.7)
(85.4)
Day
**
433
414
1337
1292
L292
Ppm
(343)
(127)
(55.7)
(65.7)
(74.0)
Day
969
1247
ppm
(358)
(132)
Day
1274
ppm
(348)
1491
(324)
% Change/month
-0.01
-0.10
-0.87
-0.12
-0.16
-0.14
-0.17
Two Std. Dev.
0.42
0.16
0.66
0.27
0.32
0.29
0.25
of % Change/month
~
~
A1 = Aluninun; S = Steel; LS = Low Pressure Steel.
~~
Cylinder enpty.
ANALYTICAL CONDITIONS: Flame ionization detector, 10% 0V-101 on Qramosorb WhP colum
at 60 degrees Celsius.
CALIBRATION: Reagent grade "Benzene" liquid is used as a standard. "Glass bulb" dilution
technique is uilized for making the series of standards for calibration.
25
-------�
1.0 BENZENE STABILITY STUDY (Continued)
Cylinder No. 1H
Cylinder Construction*** S
11
S
1J
S
IK
S
1L
S
1M
S
IN
S
Manufacturer
Concentration
PPT!
100
139
232
265
296
326
344
Date
ppn
2/8/78
(101)
2/9/78
(139)
2/9/78
(229)
2/9/78
(264)
2/9/78
(295)
2/9/78
(319)
2/9/78
(332)
Day
ppn
65
(102)
49
(139)
233
(237)
49
(261)
49
(292)
49
(316)
49
(327)
RTI
Concentration
Day
ppn
206 50
(98.0) (142)
386
(243)
50
(268)
51
(294)
51
(318)
54
(342)
Day
ppn
237
(101)
96
(139)
557
(225)
69
(254)
93
(298)
96
(323)
69
(335)
Day
ppn
434
(105)
127
(140)
W
(269)
205
(294)
433
(345)
809
(342)
Day
ppn
773
(106)
206
(138)
237
(302)
830
(335)
**
Day
ppn
831
(100)
505
(147)
809
(295)
1294
(320)
Day
ppn
1294
(92.0)
1293
(128)
12W
(290)
1338
(128)
% Change/month
-0.12
-0.16
-0.02
-0.W
-0.03
0.06
0.10
Two Std. Dev.
of % Change/month
0.21
0.12
0.62
2.51
0.06
0.17
0.16
AAA
A1 = Aliminim; S = Steel; LS = Low Pressure Steel.
**
Empty
26
-------�
1.0 BENZENE STABILITY STUDY (Continued)
Cylinder No. 10
Cylinder Construction*** S
IP
S
1Q
S
1R
S
IS
s
IT
S
1U
S
Manufacturer
Concentration
ppm
389
8.04
9.85
9.89
9.93
10.0
10.9
Date
PP
2/9/78
(387)
4/21/78
(8.37)
4/21/78
(9.99)
4/21/78
(10.0)
4/21/78
(10.0)
4/21/78
(10.7)
4/21/78
(11.5)
Day
ppm
64
(369)
4
(8.33)
5
(9.88)
4
(10.1)
4
(10.1)
25
(10.2)
4
(10.7)
RTI
Concentration
Day
ppm
205
(396)
25
(8.20)
25
(10.1)
13
(9.73)
26
(9.80)
146
(9.20)
25
(10.8)
Day
ppm
809
(396)
26
(8.34)
332
(9.71)
332
(9.77)
56
(9.50)
362
(9.90)
332
(10.7)
Day
m
1294
(389)
56
(8.19)
1018
(9.46)
146
(3.90)
1222
(9.56)
434
(10.9)
Day
ppm
134
(7.81)
1270
(9.64)
628
(9.57)
**
759
(10.2)
Day
ppm
434
(8.21)
738
(9.45)
1222
(9.69)
Day
ppm
766
(7.93)
1222
(7.68)
irk
% Change/month
0.06
-0.16
-0.25
-0.10
-0.13
-0.15
-0.29
Two Std. Dev.
of % Change/month
0.16
0.10
0.26
0.08
0.33
0.35
0.15
**
Cylinder anpty.
AAA
A1 = A1 uninun; S = Steel; LS = Low Pressure Steel.
27
-------�
1.0 BENZENE STABILITY SRJDY (Continued)
Cylinder No.
Cylinder Construction**1*
IV
' s
1W
S
IX
S
1Y
S
1Z
S
1AA
S
1AB
A1
Manufacturer
Concentration
m
12.2
8.09
11.0
11.2
8.09
9.14
270
Date
ppm
4/25/78
(12.7)
5/19/78
(8.10)
5/4/78
(U.2)
5/4/78
(10.9)
5/4/78
(3.20)
5/4/78
(9.10)
7/27/77
(300)
Day
ppm
1
(12.5)
106
(7.70)
132
(10.2)
132
(9.90)
132
(7.04)
132
(7.80)
29
(319)
RTI
Concentration
Day
ppm
21
(12.3)
287
(8.10)
**
302
(10.7)
302
(7.70)
302
(8.50)
157
(312)
Day
ppm
109
(12.0)
488
(8.20)
393
(10.8)
473
(7.54)
1005
(8.17)
Day
ppm
358
(12.1)
7W
(8.30)
1209
(8.42)
Day
ppm
755
(12.0)
1218
(11.7)
1194
(7.45)
% Change/month
-0.14
-0.09
-2.W
0.11
-0.27
-0.08
0.36
Two Std. Dev.
of % Change/month
0.09
0.25
—
1.04
1.21
0.35
—
Cylinder anpty.
AAA
A1 = Aluninun; S = Steel; LS = Low Pressure Steel.
28
-------�
2.0 ETHYLENE STABILITY STUDY
Cylinder No.
2A
2B
2C
2D
2E
2F
2G
Cylinder Construction***
f A1
A1
A1
A1
A1
A1
A1
Manufacturer
ppn
2920
3000
4960
4970
19900
19900
4.95
Concentration
Date
2/23/78
2/23/78
2/23/78
2/23/78
2/24/78
2/24/78
4/27/78
ppm
(3066)
(3127)
(5214)
(5202)
(20438)
(20622)
(4.70)
RTI
Day
49
49
48
48
48
48
29
Concentration
ppm
(3115)
(3177)
(5341)
(5284)
(20780)
(20822)
(4.70)
Day
198
198
.201
201
200
200
106
ppm
(2883)
(2942)
(4662)
(4913)
(20150)
(20320)
(4.85)
Day
809
809
809
809
808
808
741
ppm
(3203)
(3272)
(5383)
(5338)
(18906)
(18960)
(4.62)
Day
1180
ppn
(5.12)
% Change/month
0.18
0.19
0.14
0.10
-0.31
-0.32
+0.14
Two Std. Dev.
0.44
0.44
0.72
0.39
0.10
0.07
0.22
of Change/month
AAA
A1 = AT uninun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flame ionization detector, Durapak n-octane on Porasil C colinn
at 30 degrees Celsius.
CALIBRATION: NBS-SRM Propane is used for standard calibration.
29
-------�
2.0 ETHYLENE STABILITY STUDY (Continued)
Cylinder No.
2H
21
2J
2<
2L
2M
2N
Cylinder Construction*** A1
A1 .
,A1
A1
A1
A1
A1
Manufacturer
ppn
10.0
15.0
19.9
300
448
603
701
Concentration
Date
4/27/78
4/28/78
4/28/78
4/28/78
4/28/78
4/28/78
4/28/78
ppm
(9.70)
(14.4)
(19.2)
(306)
(468)
(629)
(740)
RTI
Day
29
28
28
33
33
34
34
Concentration
ppm
(9.60)
(14.4)
(19.3)
(319)
(493)
(646)
(749)
Day
106
m
104
105
104
104
104
ppm
(9.90)
(14.9)
(20.3)
(312)
(473)
(636)
(737)
Day
740
739
739
728
740
740
740
ppm
(8.40)
(18.0)
(27.5)
(300)
(457)
(606)
(703)
Day
1180
1179
1179
ppn
(10.0)
(14.4)
(18.9)
% Change/month
-0.07
0.18
+0.29
-0.17
-0.19
-0.20
-0.23
Two Std. Dev.
0.44
0.66
1.14
0.22
0.27
0.14
0.08
of % Change/month
AAA
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
30
-------�
3.0 PROPYLENE STABILITY STUDY
Cylinder No.
3A
3B
3C
3D
3E
3F
3G
3H
Cylinder Construction*** A1
A1
A1
A1
A1
A1
A1
A1
Manufacturer
ppn
4.94
9.91
14.8
20.0
298
446
585
683
Concentration
Date
4/27/78
4/27/78
4/27/78
4/27/78
4/27/78
4/27/78
4/27/78
4/27/78
ppm
(4.86)
(9.83)
(14.6)
(19.8)
(296)
(442)
(577)
(672)
Day
26
26
26
27
27
27
27
27
ppm
(4.94)
(9.85)
(14.5)
(19.0)
(286)
(428)
(560)
?655)
RTI
Day
27
104
104
104
104
105
104
105
Concentration
ppm
(4.78)
(10.3)
(14.8)
(20.0)
(317)
(474)
(629)
(729)
Day
104
749
749
749
750
750
750
750
ppm
(4.98)
(9.76)
(14.8)
(20.3)
(324)
(479)
(620)
(721)
Day
749
1250
820
820
ppm
(4.93)
(9.63)
(328)
(725)
% Change/month
0.05
-0.08
0.06
0.16
0.38
0.33
0.27
0.25
Two Std. Dev.
0.17
0.12
0.09
0.25
0.29
0.47
0.56
0.32
of % Change/month
AAA
A1 = A1 iminun; S = Steel; LS = Low Pressure Steel.
ANALYTIC/L CONDITIONS: Flare ionization detector, Durapek n-octane on Porasil C col urn at 30 degrees
Celsius
CALIBRATION: NBS-SRM Propane is used for standard calibration.
-------�
4.0 NETHANE/ETHANE STABILITY STUDY
Cylinder No. 4A 48 4C 40
Cylinder Construction*** A1 A1 A1 A1
Audit Material****
M
E
M
E
M
E
M
E
Manufacturer
Concentration
ppm
6000
714
8130
597
1000
295
1670
202
Date
ppm
7/21/78
(6207)
7/21/78
(773)
7/21/78
(8130)
7/21/78
(654)
7/21/77
(1021)
7/21/77
(315)
7/21/77
(1710)
7/21/77
(220)
RTI
Concentration
Day
ppm
Day
m
264
(5982)
662
(6584)
163
(715)
264
(684)
35
(7551)
264
(7824)
35
(663)
163
(606)
264
(983)
1027
(1289)
163
(292)
264
(283)
35
(1563)
264
(1640)
29
(218)
157
(202)
Day
ppn
662
(703)
662
(8592)
264
(577)
1027
(284)
1027
(1953)
258
(195)
Day
PP
662
(598)
1027
(206)
% Change/month
0.32
-0.34
0.43
-0.43
0.90
-0.20
0.59
-0.13
Two Std. Dev.
of % Change/month
—
0.61
0.53
0.57
—
0.36
0.41
0.39
***
A1 = Aluninun; S = Steel; IS = Low Pressire Steel.
M = Methane; E = Ethane.
ANALYTICAL CONDITIONS: Flame ionization detector, Durapak n-octane on Porasil C col urn at 30 degrees
Celsius.
CALIBRATION: N3S-SRM methane is used for standard calibration.
32
-------�
5.0 PROPANE STABILITY STUDY
Cylinder No. 5A
Cylinder Construction*** A1
58
A1
5C
A1
5D
A1
5E
A1
5F
A1
5G
A1
5H
A1
Manufacture-
Concentration
PPn
5.01
10.0
14.6
20.0
303
439
6C4
708
Date
ppn
4/25/78
(4.90)
4/25/78
(9.70)
4/25/78
(14.3)
4/25/78
(19.5)
4/26/78
(304)
4/26/78
(441)
4/26/78
(615)
4/27/78
(730)
Day
ppn
24
(4.90)
24
(9.80)
25
(14.5)
25
(19.8)
24
(301)
24
(436)
27
(615)
26
(723)
RTI
Concentration
Day
PPn
108
(5.10)
108
(10.1)
108
(14.9)
108
(20.3)
107
(305)
107
(440)
107
(607)
106
(710)
Day
ppn
606
(4.89)
513
(10.6)
582
(15.0)
582
(20.8)
530
(316)
530
(450)
604
(613)
603
(718)
Day
ppn
729
(5.20)
752
(10.0)
736
(14.7)
736
(20.1)
581
(316)
581
(453)
735
(628)
734
(734)
Day
ppn
914
(10.0)
1252
(19.7)
735
(313)
728
(472)
Day
ppn
752
(314)
Day
ppn
913
(309)
1251
(296)
% Change/month
0.11
0.09
0.10
0.01
0.01
0.25
0.08
0.3
Two Std. Dev.
of % Change/month
0.26
0.22
0.16
0.14
0.12
0.12
0.10
0.13
A1 = A1 uninun; S = Steel, LS = Low Pressure Steel.
ANALYTICAL GONDITIONS: Flane ionization detector, Dirapak n-octane on Porasil C col urn at 30 degrees
Celsius.
CALIBRATION: N3S-SRM Propane is used for standard calibration.
-------�
6.0 TOLUENE STABILITY STUDY
Cylinder No.
Cylinder Construct ion***'
6A
LS
6B
LS
6C
S
6D
S
Manufacture-
Concentration
ppn
408
606
16.2
9.11
Date
ppn
12/6/78
(405)
12/6/78
(585)
10/3/78
(17.3)
10/3/78
(9.62)
RTI
Concentration
Day
ppn
3
(405)
3
(579)
48
(14.9)
64
(8.50)
Day
ppn
86
(394)
86
(577)
365
(15.0)
• 66
(8.60)
Day
ppm
100
(393)
358
(615)
1046
(8.91)
160
(8.20)
Day
ppm
iek
982
(491)
**
Day
ppn
985
(487)
% Change/month
-0.93
-0.50
-0.72
-2.6 7
Two Std. Dev.
of % Change/month
0.07
0.29
0.56
1.97
Cylinder enpty.
AAA
AT = Alinrinim, S = Steel, LS = Low Pressure Steel.
ANALVTIC/l CONDITIONS: Flare ionization detector, 10% 0V-101 Chrarosorb W-IP colunn
at 60 degrees Celsius.
CALIBRATION: Reagent g-ade "Toluene" liquid is used as a standard. "Glass bulb" technique is
utilized for generation of series of standards for calibration.
ANALTYICAL PROBLEMS: All analyses of Cylinder No. 6B before Day 982 and of Cylinder No. 6C
before Day 1046 used glass calibration bulbs at roan tenperature rather
than bulbs vJiich were heated to cbove toluene's boiling pint. As a
result, toluene may have condensed on the walls of the roam-tenperature
bulbs. This may explain viiy the earlier concentrations are greater than
those of the most recent analyses. However, actual degradation may ha/e
occurred in these cylinders.
34
-------�
7.0 HYDROGEN SULFIDE STABILITY STUDY
Cylinder No.
7A
7B
7C
7D
7E
7F
Cylinder Construction***
A1
A1
A1
A1
A1
A1
Manufacturer
ppn
399
9.15
16.7
649
6.95
6.45
Concentration
Date
10/1/78
7/7/78
10/1/78
10A/78
10/1/78
10/1/78
ppm
(371)
(9.73)
(16.1)
(641)
(7.05)
(4.94)
R7I
Day
38
87
38
38
87
38
Concentration
ppm
(424)
(6.72)
(16.5)
(655)
(5.75)
(5.14)
Day
111
124
111
111
124
111
ppm
(414)
(7.11)
(15.7)
(690)
(5.62)
(4.81)
Day
1030
197
580
1030
197
580
ppm
(437)
(6.36)
(16.2)
(647))
(5.23)
(4.35)
Day
696
1030
696
1030
ppm
(6.23)
(17.5)
(5.14)
(3.71)
Day
1116
1116
ppm
(8.32)
(5.38)
% Change/month
0.28
-0.05
+0.22
-0.05
-0.43
-0.75
Two Std. Dev.
0.47
1.24
0.20
0.28
0.67
0.16
of % Change/month
~
Cylinder enpty.
AAA
A1 = Aluninun, S = Steel, LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flans ionization detector, 10% 0V-101 Chromosorb MHP col urn
at 60 degrees Celsius.
CALIBRATION: Reagent g-ade pire "Hydrogen sulfide" gas is used as a standard. Dilutions are made
in a Tedlcr bag for generation of series of standards for calibration.
ANALTYICAL PROBLEMS: All analyses of Cylinder No. 6B before Day 982 and of Cylinder No. 6C
before Day 1046 used glass calibration bulbs at roan tonperature rather
than bulbs v^hich were heated to above toluene's boiling pint. As a
result, toluene may have condensed on the walls of the rocm-tenperature
bulbs. This may explain nhy the earlier concentrations are greater than
those of the most recent analyses. However, actual degradation may have
occurred in these cylinders.
35
-------�
8.0 M-XYLENE STABILITY STUDY
Cylinder No.
Cylinder Construction***
84
LS
SB
LS
8C
S
8D
S
Manufacturer
Concentration
ppn
405
613
17.3
7.33
Date
ppn
10/5/78
(480)
10/5/78
(720)
10/5/78
(16.6)
10/5/78
(6.20)
Day
ppm
63
(445)
63
(676)
63
(17.2)
63
(6.81)
RTI
Concentration
Day
ppm
IS
(425)
158
(656)
166
(20.8)
166
(6.82)
Day
m
412
(487)
606
(760)*
302
(16.4)
948
(4.36)*
Day
ppm
606
(507)*
1040
(534)
918
(14.1)*
1036
(5.66)
Day
ppm
1040
(364)
1036
(19.0)
% Change/month
0.35**
-1.65**
0.24
-0.41
Two Std. Dev.
of % Change/month
0.74
0.77
0.84
0.63
~
Questionable value. Not included in the calculation of % change/month.
irk
Calculated only through Day 412 because of change in analytical procedures as
described under analytical problems.
kkk
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
CALIBRATION: Reagent grade "M-Xylene" liquid is used. "Glass bulb" technique is used
for genertion of series of standards for calibration.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on Chrcmosorb WP
colunn at 60, 120 or 140 degrees Celsius.
ANALYTICAL PROBLEMS: All analyses before Day 948 used glass calibration bulbs at room tenperature
rather then bulbs which were heated to ebo/e meta-xylene's boiling point. As a
result, meta-xylene may have condensed on the walls of the rocm-temperature
bulbs. This may explain tfiy the RTI concentration for cylinder Nos. 8A and 8B
before day 1040 are greater than those for the analysis on Day 1040.
36
-------�
9.0 METHYL ACETATE STABILITY STUDY
Cylinder No.
9A
96
9C
9D
Cylinder Construction***
S
S
S
S
Manufacturer
m
326
455
6.m
17.2
Concentration
Date
10/13/78
10/13/78
10/13/78
10/13/78
m
(271)
(428)
(5.29)
(12.9)
RTI
Day
230
230
230
230
Concentration
ppm
(340)
(437)
(4.86)
(12.5)
Day
285
286
286
286
ppm
(324)
(442)
(5.02)
(11.8)
Day
629
629
630
630
ppm
(348)
(479)
(5.88)
(12.5)
% Change/month
1.15
0.60
0.68
-0.13
Two Std. Dev.
1.08
0.21
1.13
0.56
of % Change/month
AAA
A1 = Alinrinun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% OV-275 on Chromosorb VHP
colimn at 50 degrees Celsius.
CALIBRATION: Reagent grade "Methyl acetate" liquid is used as a standard.
"Glass bulb" technique is utilized for generation of series of
standards for calibration.
37
-------�
10.0 CHLOROFORM STABILITY STUDY
Cylinder No.
Cylinder Construction***
10-A
S
10-8
S
10-C
S
10-0
s
Manufacturer
Concentration
ppn
520
348
8.70
16.9
Date
ppm
10/17/78
(529)
10/17/78
(345)
10/17/78
(8.08)
10/17/78
(17.6)
RTT
Concentration
Day
ppm
161
(515)
161
(351)
161
(7.39)
161
(16.5)
Day
ppm
256
(514)
256
(340)
256
(7.50)
256
(16.2)
Day
ppm
553
(531)
975
(325)
553
(8.11)
553
(16.5)
% Change/month
0.06
-0.20
0.14
-0.29
Two Std. Dev.
of % Change/month
0.31
0.12
0.88
0.51
***
A1 = Aluninim; S = Steel; LS = Low Pressire.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on Chromosorb WP
colimn at 50 or 100 degrees Celsius.
CALIBRATION: Reagent grade "Chloroform" liquid is used as a standard. "Glass
bulb" technique is utilized for generation of series of
standards for calibration.
38
-------�
11.0 CARBONYL SULFIDE STABILITY STUDY
Cylinder No.
Cylinder Construction***
11-A
S
11-B
S
11-C
s
11-D
S
11-E
AL
11-F
AL
Manufacturer
Concentration
ppn
251
100
9.96
7.03
9.54
101
Date
ppm
11/3/78
(276)
11/3/78
(109)
11/3/78
(9.10)
11/3/78
(6.81)
9/18/81
(12.9)
9/18/81
(111)
RTI
Concentration
Day
ppm
78
(281)
78
(111)
78
(8.66)
78
(6.48)
Day
ppm
185
(275)
~
185
(95)
~
185
(8.23)
~
185
(6.41)
~
% Change/month
-0.09
-2.13
-1.55
-0.92
**
**
Two Std. Dev.
of % Change/month
—
—
—
—
—
—
~
Cylinder onpty.
Calculations fbr % change/month are only done vlien three or rare analyses
are available.
Akk
A1 = Aluninun; S = Steel; US = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare photcmetric detector, Carbopak B col urn at 50 degrees Celsius or
Chrcmosil 330 colim at 60 degrees Celsius.
CALIBRATION: Reagent grade pure "Carbonyl Sulfide" gas is used as a standard. Dilutions are made in
Teflon® bag fbr generation of series of standards for calibration.
ANALYTICAL PR08LEMS: Chly a Teflon colum and Teflon lines should be used. The air-to-hydrogen
ratio is critical to the sensitivity of the FPD.
39
-------�
12.0 MTTHYL NERCAFTAN STABILITY STUDY
Cylinder No.
12-A
12-B
12-C
12-D
Cylinder Construction***
A1
A1
A1
A1
Manufacturer
ppn
8.03
10.0
3.55
4.22
Concentration
Date
1/24/79
1/24/79
1/24/79
1/24/79
ppn
(5.66)
(7.94)
(3.65)
(4.23)
RTI
Day
1M
104
104
104
Concentration
ppn
(5.60)
(8.10)
(3.50)
(4.76)
Day
139
139
139
139
ppm
(5.65)
(7.90)
(3.56)
(4.54)
985
985
985
~
(5.40)
(8.42)
(3.64)
% Change/month
-0.14
0.18
0.05
2.04
Two Std. Dev.
0.04
0.10
0.17
of % Change/month
A1 = A1 Lminim; S = Steel; LS = Low Pressure Steel.
~
Empty
ANALYTICAL CONDITIONS: Flame photcmetric detector, Carbopak B col am at
50 degrees Celsius or Chrcmosil 330 col urn at
60 degrees Celsius.
CALIBRATION: Reagent grade pure "Methyl mercaptan" gas is used a standard.
Dilutions are made in a Teflorf® bag for generation of series
of standards for calibration.
ANALYTICAL PROBLEMS: Only a Teflon colimn and Teflon lines should be used.
The air-to-hydrogen ratio is a critical variable.
40
-------�
13.0 HEXANE STABILITY STUDY
Cylinder No.
13-A
13-3
13-C
13-D
Cylinder Construction***
LS
LS
A1
A1
Manufacturer
ppn
1975
2973
30.6
79.2
Concentration
Date
2/6/79
2/6/79
2/6/79
2/6/79
ppn
(2170)
(3070)
(30.8)
(82.2)
RTI
Concentration
Day
6
6
296
296
ppn
(1982)
(2855)
(30.1)
(81.0)
Day
337
338
337
337
ppn
(2069)
(2946)
(30.6)
(81.3)
Day
469
469
469
469
ppn
(1986)
(3076)
(32.0)
(79.8)
Day
523
835
ppn
(30.0)
(80.2)
Day
835
ppn
(30.2)
% Change/month
-0.22
0.16
-0.05
-0.09
Two Std. Dev.
0.®
0.60
0.26
0.C8
of % Change/month
AAA*
A1 = Aluninun; S = Steel; l_S = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on Chrorosorb kHP
colunn at 60 or 100 degrees Celsius.
CALIBRATION: Reagent grade "Hexane" liquid is used as a standard. "Glass bulb"
technique is utilized for making series of standards for calibration.
41
-------�
14.0
1,2 DICHLCROETHANE (ETHYLENE DICHLCRIDE) STABILITY STUDY
Cylinder No.
14A
14B
14C
14D
14E
14F
14G
14H
Cylinder Construction***
A1
A1
A1
A1
A1
A1
A1
A1
Manufacture'
ppn
14.4
9.64
100
526
6.92
12.5
97.9
439
Concentration
Date
1/19/79
1/19/79
1/19/79
1/19/79
4/5/79
4/5/79
4/5/79
4/5/79
ppm
(14.1)
(9.20)
(96.2)
(498)
(10.0)
(15.2)
(102)
(463)
RTI
Day
58
58
58
58
30
30
30
30
Concentration
ppm
(15.2)
(10.8)
(103)
(534)
(9.42)
(14.7)
(105)
(451)
Day
155
155
155
155
69
69
69
69
ppm
(14.9)
(10.0)
(98.2)
(524)
(9.30)
(14.3)
(99.0)
(462)
Day
811
811
501
501
586
811
425
589
ppm
(14.2)
(9.56)
(87.3)
(592)
(9.14)
(14.5)
(87.3)
(432)
Day
835
835
920
920
811
835
m
697
ppm
(13.5)
(9.19)
(102)
(502)
(9.70)
(13.8)
(101)
(451)
Day
835
m
ppm
(9.16)
(453)
% Change/month
-0.22
-0.23
-0.01
+0.04
-0.09
-0.16
-0.18
-0.10
Two Std. Dev.
0.28
0.50
oo
LO
o
0.64
0.25
0.21
0.62
0.16
of % Change/month
kk'k
A1 = A1 uninun; S = Steel; IS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% OV-101 on Chrorosorb WP colum at Id) degrees
Celsius.
CALIBRATION: Reagent grade "1,2 Dichloroethane" liquid is used as a standard. "Glass bulb" technique
is utilized for making series of standards for calibration.
-------�
15.0 CYCLOHEXANE STABILITY STUDY
Cylinder No.
15-A
Cylinder Construction***
A1
Manufacturer
ppn
99.1
Concentration
Date
3/19/79
RTI
PPn
(106)
Concentration
Day
147
ppn
(93.4)
Day
394
ppn
(99.0)
926
(102)
% Change/month
0.02
Two Std. Dev.
0.55
of % Change/ronth
***
A1 = Aliminun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flame ionization detector, 10% 0V-101 on
Chromosorb WHP colimn at 100 degrees Celsius.
CALIBRATION: Reagent grade "Cy:lohexane" liquid is used as a standard.
"Glass bulb" technique is used for making series of
standards for calibration.
43
-------�
16.0 METHYL ETHYL KETONE STABILITY STUDY
Cylinder No.
16-A
Cylinder Construction***
S
Manufacturer
ppn
43.7
Concentration
Date
5/23/79
ppn
(42.3)
-RTI
Day
28
Concentration
ppm
(40.0)
Day
58
ppm
(39.9)
Day
380
Ppn
(44.5)
Day
653
ppn
(38.7)
% Change/month
-0.08
Two Std. Dev.
0.67
of % Change/month
AAA
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, Chrarosorb 101
colimn at 180 degrees Celsius.
CALIBRATION: Reagent grade "Methyl ethyl ketone" liquid is used as a
standard. "Glass bulb" technique is utilized for making
series of standards for calibration.
44
-------�
17.0 METHANOL STABILITY STUDY
Cylinder No.
17-A
Cylinder Construction***
A1
Manufacture-
ppn
50.0
Concentration
Date
5/17/79
ppn
(58.8)
RTI
Day
21
Concentration
ppm
(52.3)
Day
51
ppn
(51.1)
Day
196
PP
(55.2)
% Change/month
-1.03
Two Std. Dev.
3.01
of % Change/month
AAA
A1 = Alimirum; S = Steel; US = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, Chrorosorb 101 colurm
at 50 degrees Celsius or 0.2% Carbowax 1500 plus
0.1% SP-2100 on Carbowax C at 60 degrees Celsius.
CALIBRATION: Reagent grade "Methanol" is used as a standard. "Glass
bulb" dilution technique is utilized for making series
of standards for calibration.
45
-------�
18.0 1,2-DICHLCROPROPANE (PROPYLENE DICHLCRIDE) STABILITY STUDY
Cylinder No.
Cylinder Construction***
ISA
A1
188
A1
18C
A1
18D
A1
Manufacturer
Concentration
ppn
7.07
14.6
476
664
Date
ppn
7/10/79
(6.06)
7/10/79
(15.6)
7 AO/79
(496)
7/10/79
(685)
RTT
Concentration
Day
Ppn
28
(5.52)
28
(16.4)
28
(455)
28
(621)
Day
ppn
48
(5.94)
48
(15.0)
48
(480)
48
(675)
Day
ppn
497
(6.03)
749
(16.3)
372
(497)
372
(685)
Day
ppn
749
(5.59)
% Change/month
-0.09
+0.16
+0.33
+0.30
Two Std. Dev.
of % Change/month
0.43
0.43
0.89
1.05
kkk
AT = A1 Lminun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flame ionization detector, 10% 0V-101 on Chrcmosorb WP
colunn at 100 degrees Celsius.
CALIBRATION: Reagent grade "1,2-Dichloropropane" liquid is used as a standard.
"Glass bulb" dilution technique is utilized for making series of
standards for calibration.
46
-------�
19.0 TRICHLCROETHYLENE STABILITY STUDY
Cylinder No.
Cylinder Construction***
19A
A1
1SB
A1
19C
A1
19D
A1
Manufacturer
Concentration
ppn
9.23
14.7
100
505
Date
ppm
5/24/79
(9.58)
5/24/79
(14.3)
5/24/79
(102)
5/24/79
(506)
RTI
Concentration
Day
ppm
77
(10.2)
77
(15.1)
77
(103)
77
(503)
Day
PPn
92
(9.78)
92
(14.9)
92
(100)
92
(499)
Day
ppm
683
(9.03)
683
(13.6)
810
(105)
810
(522)
820
(8.91)
820
(13.5)
820
(94.6)
820
(490)
% Change/month
-0.37
-0.33
-0.08
0.02
Two Std. Dev.
of % Change/month
0.23
0.21
0.31
0.19
¦Hck
A1 = Aliminun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on Chrcmosorb WP
colimn at 100 degrees Celsius.
CALIBRATION: Reagent grade "Trichloroethylene" liquid is used as a standard.
"Glass bulb" technique is used for making series of standards
for calibration.
47
-------�
20.0 1,1-DICHLCR0ETHYLENE (VINYLIDENE CHLORIDE) STABILITY STUDY
Cylinder No.
2QA
2C8
20C
2CD
Cylinder Construction*"**
A1
A1
A1
A1
Manufacturer
ppn
9.58
14.8
96.8
490
Concentration
Date
6/1/79
6/1/79
6/1/79
6/1/79
ppn
(10.3)
(15.6)
(101)
(524)
RTI
Day
35
35
35
35
Concentration
ppn
(9.90)
(15.1)
(99.0)
(510)
Day
62
62
62
62
ppn
(10.1)
(15.5)
(102)
(505)
Day
4M
404
817
404
ppn
(11.5)
(17.1)
(94.0)
(498)
818
818
(9.00)
(14.2)
% Change/month
-0.25
-0.17
+0.40
-0.26
Two Std. Dev.
0.81
0.63
0.14
0.31
of % Change/month
AAA
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flame ionization detector, 10% 0V-101 on Chrcmosorb WP
colum at 100 degrees Celsius or 10% SP-2100 on Supelcoport
colum at 100 degrees Celsius.
CALIBRATION: Reagent grade "1,1-Dichloroethylene" pure liquid is used as a
standard. "Glass bulb" dilution technique is utilized for making
series of standards for calibration.
48
-------�
21.0 1,2-DIBR0M0ETHYLENE (ETHYLENE DIBRCMIDE) STABILITY STUDY
Cylinder No.
21A
21B
21C
21D
Cylinder Construction***
LS
LS
LS
LS
Manufacturer
ppn
10.0
14.9
99.9
301
Concentration
Date
6/18/79
6/18/79
6/1/79
6/18/79
ppm
(7.90)
(12.2)
(110)
(265)
RTI
Day
61
61
61
61
Concentration
ppn
(7.80)
(12.0)
(107)
(266)
Day
89
89
89
89
ppm
(7.40)
(11-6)
(105)
(257)
Day
722
772
787
643
ppm
(7.72)
(8.02)
(99.2)
(309)
% Change/month
-1.90*
-1.53*
-1.52*
-0.83*
Two Std. Dev.
0.35
0.10
0.17
0.29
of % Change/month
*
% change/month is calculated for only the first three analyses and are approximate
because of change in calculation procedure as-described below in the analytical
problens.
A AA
A1 = Aluninim; S = Steel; LS = Low Pressire Steel.
ANALYTIC/^ CONDITIONS: Flcme ionization detector, 10% 0V-101 on Chrcmosorb W4P colunn
at 100 degrees Celsius.
CALIBRATION: Reagent grade "1,2-Dibrcmoethylene" pure liquid is used as a standard.
"Glass bulb" dilution techniques is utilized for making series of
standards for calibration.
ANALYTICAL PROBLEMS: The gas mixtures and the cal ibration standards contain
substantial anoints of both the cis and the trans iscmers
of 1,2-Dibrcmoethylene. The first three sets of analyses
are questionable because only one isaner was measured during
the calibrations and cylinder analyses.
49
-------�
22.0 PERCHLOROETHYLENE STABILITY STUDY
Cyl inder No.
22A
22B
22C
22D
Cylinder Construction***
S
S
LS
LS
Manufacturer
ppm
7.98
13.0
487
629
Concentration
Date
7/6/79
7/6/79
7/6/79
7/6/79
ppn
(8.40)
(15.0)
(419)
(624)
RTI
Day
35
35
35
35
Concentration
ppn
(7.97)
(14-9)
(453)
(642)
Day
52
52
52
52
ppm
(7.92)
(14.7)
(440)
(619)
Day
376
376
677
677
ppm
(7.94)
(14.5)
(361)
(542)
713
713
(387)
(571)
% Change/month
-0.22
-0.23
-0.63
-0.51
Two Std. Dev.
0.61
0.17
0.37
0.22
of % Change/month
AAA
A1 = A1 rniiniri; S = Steel; LS = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on Chrcmosorb WHP
colimn at 50 or 100 degrees Celsius.
CALIBRATION: Reagent grade "Perchloroethylene" liquid is used as a standard.
"Glass bulb" dilution technique is utilized for making series of
standards for cal ibration.
50
-------�
23.0 VINYL CHLCRICE STABILITY STUDY
Cylinder No.
23A
23B
23C
230
23E
23F
23G
23H
231
Cylinder Construction***
S
S
S
S
S
S
S
S
S
Manufacture-
ppn
5.S4
8.00
8.03
8.52
20.0
20.1
30.0
30.3
7.98
Concentration
RTI
Date
10/1/79
10/1/79
10A/79
10/1/79
10/1/79
10/1/79
10 A/79
10/1/79
10A/79
Concentration
ppn
(5.87)
(7.71)
(7.82)
(7.85)
(19.7)
(20.1)
(29.6)
(29.8)
(7.31)
18
18
18
18
18
18
18
18
18
(5.74)
(7.50)
(7.45)
(7.61)
(19.1)
(19.3)
(28.3)
(28.7)
(7.12)
700
700
700
700
700
700
700
700
(6.60)
(8.44)
(8.41)
(20.7)
(20.9)
(30.4)
(29.4)
(8.39)
% Change/month
0.59
¦**
0.45
0.38
0.29
0.25
0.01
0.01
0.71
• Calculations for % change/month are only done nhen three or more analyses are avail able.
¦kirk
A1 = Aluninun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flane ionization detector, 0.4% Carbowax 1500 on Carbopak C at 50 degrees Celsius.
CALIBRATION: Vinyl chloride permeation tibe purchased from Metronics is used for calibration. Permeation
tube is maintained at 30°C.
51
-------�
24.0 1,3 BUTADIENE STABILITY STUDY
Cylinder No.
24A
Cylinder Construction***
S
Manufacturer
ppm
22.6
Concentration
RTI
Date
3/21/80
Concentration
ppm
(20.9)
Date
95
m
(23.1)
Day
480
ppn
(24.0)
% Change/month
+0.73
kkk
A1 = Aliminun; S = Steel; LS = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 0.1% SP-1000 on
Carbopak C colum at 90 degrees Celsius or
10% 0V-101 on Chrorrosorb WHP colum at
60 degrees Celsius.
CALIBRATION: Reagent grade "1,3 Butadiene" liquid is used as a
standard. "Glass bulb" dilution technique is utilized
for making series of standards for calibration.
52
-------�
25.0 ACRYLONITRILE STABILITY STUDY
Cylinder No.
25A
25B
25C
25D
Cylinder Construction***
LS
LS
LS
LS
Manufacturer
PPn
20.1
348
11.7
638
Concentration
Date
7/24/79
7/24/79
7/24/79
7/24/79
m
(14.6)
(411)
(6.38)
(678)
RTI
Day
185
185
185
185
Concentration
ppm
(12.7)
(416)
(3.35)
(699)
Day
349
349
349
349
ppm
(13.2)
(441)
(2.87)
(703)
Day
841
841
841
841
ppm
(9.96)
(397)
(4.05)
(667)
% Change/month
-1.07
-0.14
-1.12
-0.10
Two Std. Dev.
0.46
0.47
3.49
0.26
of % Change/month
***
A1 = Aluninim; S = Steel; LS= Low Pressure Steel
ANALYTICAL CONDITIONS: Plane ionization detector, 4% Carbowax 2CM
on Carbopak B at 50 or 150 degrees Celsius
CALIBRATION: Acrylonitrile permeation tibe is used for GC-FID cali-
bration. Permeation tube is maintained at 30°+_0.1°C.
ANALYTICAL PROBLEMS: The large changes noted at the lew concentration
levels are, at least in part, a result of
difficulty in making precise measuranents at
these levels.
53
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26.0 ANILINE STABILITY STUDY
Cylinder No.
26A
26B
Cylinder Construction***
A1
A1
Manufacturer ppn
11.3
18.4
RTI See Analytical Problems
Analysis
•kick
A1 = Aluninun; S = Steel; LS = Low Pressure Steel
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101 on
Chrcmosorb WHP colimn at 250 degrees Celsius.
CALIBRATION: Reagent grade "Aniline" pure liquid is used as a
standard. "Glass bulb" dilution technique is utilized
for making series of standards for calibration.
ANALYTICAL PROBLEMS: Because aniline has an extronely high boiling
point (186°C), special handling would be
required to measure this canpoind. A
completely heated systan for sampling in the
vapor phase and for preparing standards would
be required. Temperature-dependent conden-
sation in the cylinder and the regulator
causes the anouit of aniline which is
delivered by the cylinder to vary. As a
result, aniline is not considered to be
practical as an audit material.
54
-------�
27.0 .METHYL ISCBUTYL KETCME STABILIPC STUDY
Cylinder No.
27A
27C
Cylinder Construction*** A1
A1
Manufacturer
ppn 9.51
72.9
Concentration
Date 12/18/80
7/8/81
ppm (10.2)
(75.4)
RTI
Day 27
See Analytical
Concentration
ppm (10.6)
Problems
Day 83
ppm (9.53)
Day 202
ppm (9.49)
% Change/month
-1.40
Two Std. Dev.
1.58
of % Change/month
Calculations for % change/month are only done viien tlree or rrore
analyses are available.
AAA
A1 = Aluninim; S = Steel; LS = Low Presstre Steel
ANALYTIC/1 CONDITIONS: Flare ionization detector, 0.1% SP-1000 on
Carbopak C col iron at 180° degrees Celsius.
CALIBRATION: Reagent grade "Methyl isobutyl ketone" liquid is used
as a standard. "Glass bulb" technique is utilized
for making series of standards for calibration.
ANALYTICAL PROBLEMS: Methyl isobutyl ketone at high concentra-
trations is not practical as an audit
material because pressirization of the
cylinder above approximately 200 psi
results in condensation of the analyte.
55
-------�
28.0 CYCLOHEXANONE STABILITY STUDY
Cylinder No.
28A
2S8
Cylinder Construction***
A1
A1
Manufacturer
ppn
10.1
19.0
Concentration
RTI
Date
12/11/8)
12/11/80
Analysis
ppm
(8.19)
(25.5)
Day
85
85
ppm
(3.26)
(17.1)
% Change/month
**
**
Calculations for % change/month are only done i«hen three or more
analyses are available.
AAA
A1 = Aluninun; S = Steel; LS = Low Pressure Steel
ANALYTICAL CONDITIONS: Flare ionization detector, 10% SP-1000 on Supelco-
port colimn at 200 degrees Celsius.
CALIBRATION: Reagent grade "Cyzlohexanone" liquid is used as a
standard. "Glass bulb" technique is used for making
series of standards for calibration.
ANALYTICAL PROBLEMS: The analysis of cyrlohexanone gas is dependent on
the temperatures of the cylinde- and the regulator
and on the length of the sampling line between the
regulator and the gas chronatograph. The concen-
tration in the cylinder decreases with time.
Therefore, cyzlchexanone is not practical as an
audit material.
56
-------�
29.0 PARADICHLCRCBENZENE STABILITY STUDY
Cylinder Mo.
2SA 29B
Cylinder Construction***
S S
Manufacturer ppm
15.6 38.1
Concentration
RTI
See Analytical Problems
Analysis
AAA
AT = Aliminun; S = Steel; LS = Low Pressure Steel
ANALYTICAL CONDITIONS: Flare ionization detector, 10% SP-1000 on
Supelcoport col urn at 200 degrees Celsius.
CALIBRATION: Reagent grade "Paradichlorobenzene" is used as a
standard. "Glass bulb" technique is used for making
series of standards for calibration.
ANALYTICAL PROBLEMS: The stability study for this compound was
terminated bacause of analytical difficulties
and because the cylinder pressure was less than
200 psig. Paradichlorobenzene is a solid at
room temperature with a melting pint of 54°C.
Condensation in the cylinder, regulator and
sampling lines was extreme. Paradichloro-
benzene is not practical as an audit material.
57
-------�
30.0 ETHYLAMINE STABILITY STUDY
Cylinder No.
30A 3G6
Cylinder Construction**11'
S S
Manufacturer ppn
10 20
Concentration
RTI
Analysis
See Analytical Problems
AAA
A1 = aluninun; S = Steel; LS = Low Pressure Steel
ANALYTICAL CONDITIONS: Flare ionization detector, 10% 0V-101
Chrcmosorb WHP colum at 250 degrees
Celsius.
CALIBRATION: Reagent grade "Ethylamine" liquid is used as a
standard. "Glass bulb" technique is utilized for
making series of standards for calibration.
ANALYTICAL PROBLEMS: Because of vapor pressure considerations,
the cylinders could not be fully
pressurized. The pressure in the cylin-
der is less than 200 psi. A canpletely
heated systen for sampling in the vapor
phase and for preparing standards would
be required. Tanperature-dependent
condensation in the cylinder and the
regulator causes the aroint of aniline
which is delivered by the cylinder to
vary. As a result of these problems,
ethylamine is not considered to be
practical as an audit material.
58
-------�
31.0 FORMALDEHYDE STABILITY STUDY
RTI
Requested ppm 10 20
Concentration
The speciality gas supplier indicated that they could not
make gas mixtures containing formaldehyde.
59
-------�
32.0 METHYLENE CHLORIDE
Cylinder No.
32A
Cylinder Construction*
A1
Manufacture'
ppn
10.2
Concentration
RTT
Date
3/5/82
Concentration
ppm
(10.8)
Day
31
ppm
(10.8)
Day
70
ppm
(10.6)
% Change/month
0.68
~
A1 = Aliminun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 20 ft. x
1/8" SS colimn packed with 10% SP-1000
on 80/100 Supelcoport. 30 cm^/minute
hfe carrie- gas. Colum tarp. = 100°C.
Detector temp. = 175°C.
CALIBRATION: Reagent grade "Methylene chloride" liquid is used
as a standard. "Glass bulb" technique is utilize
for making series of standards for calibration.
60
-------�
33.0 CARBON TETRACHLORIDE
Cylinder Mo.
33A
Cylinder Construction*
AL
Manufacturer
ppn
11.3
Concentration
RTI
Date
3/4/82
Concentration
Ppn
(12.7)
Day
74
ppm
(11.7)
~
A1 = Aluninun; S = Steel; LS = Low Pressure Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 20 ft. x
1/8" SS col urn packed with 10% SP-1000
on 80/1000 Supelcoport. 30 cnr/minute
He carrier gas. Colum tarp. = 1008C.
Detector tenp. = 175°C.
CALIBRATION: Reagent grade "Carbon tetrachloride" liquid is used
as a standard. "Glass bulb" dilution technique is
utilized for making series of standards for cali-
bration.
61
-------�
34.0 FREOM 113
Cylinder No.
34A
Cylinde" Construction*
A1
Manufacture-
ppn
10.4
Concentration
RTI
Date
3/3/82
Concentration
ppm
(10.8)
Day
34
ppm
(10.1)
Day
70
ppm
(10.0)
% Change/month
-3.08
~
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
ANALYTICAL CONDITIONS: Flare ionization detector, 20 ft. x
1/8" SS col urn packed with 10% SP-1000
on 80/100 Supelcoport. 30 on^/minute
Hs carrier gas. Colum taip. = 100°C.
Detector tanp. = 175"C.
CALIBRATION: Reagent grade "Freon 113" liquid is used as a
standard. "Glass bulb" dilution technique is
utilized for making series of standards for cali-
bration.
G2
-------�
35.0 METHYL CHLCRCFORM
Cylinder No.
35A
Cylinder Construction*
A1
Manufacturer
ppn
10.2
Concentration
RTI
Date
3/2/82
Concentration
ppm
(10.3)
Day
70
ppm
(11.8)
~
A1 = Aluninun; S = Steel; LS = Low Pressire Steel.
ANALYTIC/L CONDITIONS: Flare ionization detector, 20 ft. x 1/8"
SS colunn packed with 10% SP-1000 on 80/100
Supelcoport. 30 air/minute He carrier
gas. Col urn terp. = 100°C. Detector teip.
= 175°C.
CALIBRATION: Reagent grade "Methyl chlorofonn" is used as a
standard. "Glass bulb" dilution technique is
utilized for making series of standards for cali-
bration.
63
-------�
36.0 ETHYLENE OXIDE
Cylinder No.
36A
Cylinder Construction*
A1
Manufacturer
ppti
10.0
Concentration
RTI
Date
3/12/82
Concentration
ppm
(11-2)
Day
73
ppn
(9.60)
Day
88
ppm
(9.80)
% Change/month
-4.8
~
A1 = Aluninun; S = Steel; US = Low Pressire Steel.
ANALYTIC/L CONDITIONS: Flare ionization detector, 6 ft. x
1/8" SS colimn packed with 80/100 mesh
Porapak Q5. 30 cnr/ minute He
carrier gas. Col urn tamp. = 150°C.
Detector = 175°C.
CALIBRATION: Ethylene oxide permeation tibe purchased from
Metronics is used for GC-FID calibration.
Permeation tibe is maintained at 30°C.
ANALYTICAL PROBLEMS: There appeared to be seme loss of
ethylene oxide when a brass regulator was
used on the cylinder. A stainless steel
regulator was used for the analysis.
64
-------�
37.0 PROPYLENE 0XIC6
Cylinder No.
37A
378
Cylinder Construction*
A1
A1
Requested
ppn
10.0
100
Concentration
RTI
Date
XX
XX
Concentration
ppn
~
A1 = A1 iminun; S = Steel; LS = Low Pressure Steel.
XX
Cylinders recently ordered but not yet received fron the
manufacturer.
65
-------�
38.0 ALLYL CHLCRIDE
Cylinder No.
38A
388
Cylinder Construction*
S
S
Requested
ppn
10.0
100
Concentration
RTT
Date
XX
XX
Concentration
ppm
~
A1 = Aliminun; S = Steel; LS = Low Pressire Steel.
XX
Cylinders recently ordered but not^et received fran the
manufacturer.
66
-------�
39.0 ACROLEIN
Cylinder No.
39A
39B
Cylinder Construction*
A1
A1
Requested
ppn
10.0
100
Concentration
R7I
Date
XX
XX
Concentration
ppm
~
AT = Aluninun; S = Steel; LS = Low Pressure Steel.
XX
Cylinders recently ordered but not .jet received frcm the
manufacturer.
67
-------�
40.0 CHL0R0BENZENE
Cylinder Mo. 4QA
Cylinder Construction* A1
Requested ppn 10.0
Concentration
R71 Date XX
Concentration ppn
~
A1 = Aliminun; S = Steel; LS = Low Pressure Steel.
XX
Cylinders recently ordered but not^et received frcm the
manufacturer.
63
-------�
41.0 CAR80NDISULFIDE
Cylinder No.
41A
Cylinder Construction*
A1
Manufacturer
ppn
100
Concentration
RTI
Date
XX
Concentration
PPm
~
A1 = A1 uninun; S = Steel; LS = Low Pressire Steel.
XX
Cylinders recently ordered but not >et received fran the
manufacturer.
69
-------�
ATTACHMENT 2
SAMPLE CALCULATIONS OF % CHANGE/MONTH
70
-------�
ATTACHMENT 2
Sample Calculations of % Change/Month
Example: (Data shown for benzene cylinder.)
Data:
Date of Analysis
Concentration, ppm
2/8/78
4/13/78
9/1/78
10/2/78
4/17/79
101
102
98
101
105
1) Linear Regression, X and Y Data Points, Slope
X values correspond to the dates of analyses, with the first date
being day 1 (2/8/78). The second X value is equal to the number of
calendar days (i.e., 65) between the first analysis date and the
second analysis date (4/13/78) and so on. The Y values are the
concentrations (ppm) that were determined on the respective
analysis dates.
Perform the regression analysis and determine the slope of the line
utilizing commercially-avai1 able hand calculators or by the
following formula:
X
Y
1
101
102
98
101
105
65
206
237
434
m
z(Xi-X)(Yi-Y)
0.0071
Standard deviation of slope =
-I 1/2
£(xrx)2
0.0076
(N-2) z (X.-X)c
71
-------�
m = slope of regression line
X. = x-coordinate of an individual value
l
Y. = /-coordinate of an individual value
l
X" = average of all
Y - average of all Yi
N = number of analyses
2) Percent change/month
% change/month = m (slope) x ^gg x days
where
b = y intercept = -^ (Y - bX) = 100.06
Therefore,
% change/month = °-0071 x 100 x 30 = 0.21
100.06
3) Standard deviation of percent channe/month
, , . Standard deviation of slope
Standard deviation in units = X 100 X 30 = 0 2270
of % change/month Intercept
95% Confidence interval = 0.21 + 2 X 0.2270 = (-0.255, 0.664)
for % change/month
72
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