(6)
NIOSH Method S-156 (unmodified)
Analyte: Acrylonitrile.
Matrix: Air.
Procedure: Absorption on charcoal, desorption with methanol,
GC.
(a) Principle of the method.
Reference (k)(i) of this subsection.
(i) A
known volume of air is drawn through a charcoal tube to trap the organic vapors
present.
(ii) The charcoal in the
tube is transferred to a small, stoppered sample container, and the analyte is
desorbed with methanol.
(iii) An
aliquot of the desorbed sample is injected into a gas chromatograph.
(iv) The area of the resulting peak is
determined and compared with areas obtained for standards.
(b) Range and sensitivity.
(i) This method was validated over the range
of 17.5-70.0 mg/cu m at an atmospheric temperature and pressure of 22°C and
760 mm Hg, using a twenty-liter sample. Under the conditions of sample size (20
liters) the probable useful range of this method is 4.5-135 mg/cu m. The method
is capable of measuring much smaller amounts if the desorption efficiency is
adequate. Desorption efficiency must be determined over the range
used.
(ii) The upper limit of the
range of the method is dependent on the adsorptive capacity of the charcoal
tube. This capacity varies with the concentrations of acrylonitrile and other
substances in the air. The first section of the charcoal tube was found to hold
at least 3.97 mg of acrylonitrile when a test atmosphere containing 92.0 mg/cu
m of acrylonitrile in air was sampled 0.18 liter per minute for 240 minutes; at
that time the concentration of acrylonitrile in the effluent was less than 5
percent of that in the influent. (The charcoal tube consists of two sections of
activated charcoal separated by a section of urethane foam. See (f)(ii) of this
subsection. If a particular atmosphere is suspected of containing a large
amount of contaminant, a smaller sampling volume should be taken.)
(c) Interference.
(i) When the amount of water in the air is
so great that condensation actually occurs in the tube, organic vapors will not
be trapped efficiently. Preliminary experiments using toluene indicate that
high humidity severely decreases the breakthrough volume.
(ii) When interfering compounds are known or
suspected to be present in the air, such information, including their suspected
identities, should be transmitted with the sample.
(iii) It must be emphasized that any
compound which has the same retention time as the analyte at the operating
conditions described in this method is an interference. Retention time data on
a single column cannot be considered proof of chemical identity.
(iv) If the possibility of interference
exists, separation conditions (column packing, temperature, etc.) must be
changed to circumvent the problem.
(d) Precision and accuracy.
(i) The coefficient of variation
(CVt) for the total analytical and sampling method in
the range of 17.5-70.0 mg/cu m was 0.073. This value corresponds to a 3.3 mg/cu
m standard deviation at the (previous) OSHA standard level (20 ppm).
Statistical information and details of the validation and experimental test
procedures can be found in (k)(ii) of this subsection.
(ii) On the average the concentrations
obtained at the 20 ppm level using the overall sampling and analytical method
were 6.0 percent lower than the "true" concentrations for a limited number of
laboratory experiments. Any difference between the "found" and "true"
concentrations may not represent a bias in the sampling and analytical method,
but rather a random variation from the experimentally determined "true"
concentration. Therefore, no recovery correction should be applied to the final
result in (j)(v) of this subsection.
(e) Advantages and disadvantages of the
method.
(i) The sampling device is small,
portable, and involves no liquids. Interferences are minimal, and most of those
which do occur can be eliminated by altering chromato-graphic conditions. The
tubes are analyzed by means of a quick, instrumental method.
(ii) The method can also be used for the
simultaneous analysis of two or more substances suspected to be present in the
same sample by simply changing gas chromatographic conditions.
(iii) One disadvantage of the method is that
the amount of sample which can be taken is limited by the number of milligrams
that the tube will hold before overloading. When the sample value obtained for
the backup section of the charcoal tube exceeds 25 percent of that found on the
front section, the possibility of sample loss exists.
(iv) Furthermore, the precision of the
method is limited by the reproducibility of the pressure drop across the tubes.
This drop will affect the flow rate and cause the volume to be imprecise,
because the pump is usually calibrated for one tube only.
(f) Apparatus.
(i)
A calibrated personal sampling pump whose flow can be determined
within +-5 percent at the recommended flow rate. Reference (k)(iii) of this
subsection.
(ii) Charcoal tubes:
Glass tubes with both ends flame sealed, 7 cm long with a 6 mm O.D. and a 4 mm
I.D., containing 2 sections of 20/40 mesh activated charcoal separated by a 2
mm portion of urethane foam. The activated charcoal is prepared from coconut
shells and is fired at 600°C prior to packing. The adsorbing section
contains 100 mg of charcoal, the backup section 50 mg. A 3 mm portion of
urethane foam is placed between the outlet end of the tube and the backup
section. A plug of silicated glass wool is placed in front of the adsorbing
section. The pressure drop across the tube must be less than 1 inch of mercury
at a flow rate of 1 liter per minute.
(iii)
Gas chromatograph equipped with a flame ionization
detector.
(iv) Column (4 ft
× 1/4 in stainless steel) packed with 50/80 mesh Poropak, type
Q.
(v) An electronic integrator or
some other suitable method for measuring peak areas.
(vi) Two-milliliter sample containers with
glass stoppers or Teflon-lined caps. If an automatic sample injector is used,
the associated vials may be used.
(vii)
Microliter syringes: Ten-microliter and other convenient sizes
for making standards.
(viii)
Pipets: 1.0 ml delivery pipets.
(ix)
Volumetric flask: 10 ml or convenient sizes for making standard
solutions.
(g)
Reagents.
(i) Chromatographic quality
methanol.
(ii) Acrylonitrile,
reagent grade.
(iii) Hexane,
reagent grade.
(iv) Purified
nitrogen.
(v) Prepurified
hydrogen.
(vi) Filtered compressed
air.
(h) Procedure.
(i) Cleaning of equipment. All glassware
used for the laboratory analysis should be detergent washed and thoroughly
rinsed with tap water and distilled water.
(ii)
Calibration of personal pumps. Each personal pump must be
calibrated with a representative charcoal tube in the line. This will minimize
errors associated with uncertainties in the sample volume collected.
(iii) Collection and shipping of samples.
(A) Immediately before sampling, break the
ends of the tube to provide an opening at least one-half the internal diameter
of the tube (2mm).
(B) The smaller
section of charcoal is used as a backup and should be positioned nearest the
sampling pump.
(C) The charcoal
tube should be placed in a vertical direction during sampling to minimize
channeling through the charcoal.
(D)
Air being sampled should not be passed through any hose or tubing
before entering the charcoal tube.
(E)
A maximum sample size of 20 liters is recommended. Sample at a
flow of 0.20 liter per minute or less. The flow rate should be known with an
accuracy of at least ±5 percent.
(F)
The temperature and pressure of the atmosphere being sampled
should be recorded. If pressure reading is not available, record the
elevation.
(G) The charcoal tubes
should be capped with the supplied plastic caps immediately after sampling.
Under no circumstances should rubber caps be used.
(H) With each batch of ten samples submit
one tube from the same lot of tubes which was used for sample collection and
which is subjected to exactly the same handling as the samples except that no
air is drawn through it. Label this as a blank.
(I) Capped tubes should be packed tightly
and padded before they are shipped to minimize tube breakage during
shipping.
(J) A sample of the bulk
material should be submitted to the laboratory in a glass container with a
Teflon-lined cap. This sample should not be transported in the same container
as the charcoal tubes.
(iv)
Analysis of samples.
(A)
Preparation of samples. In preparation for analysis, each charcoal tube is
scored with a file in front of the first section of charcoal and broken open.
The glass wool is removed and discarded. The charcoal in the first (larger)
section is transferred to a 2 ml stoppered sample container. The separating
section of foam is removed and discarded; the second section is transferred to
another stoppered container. These two sections are analyzed
separately.
(B) Desorption of
samples. Prior to analysis, 1.0 ml of methanol is pipetted into each sample
container. Desorption should be done for 30 minutes. Tests indicate that this
is adequate if the sample is agitated occasionally during this period. If an
automatic sample injector is used, the sample vials should be capped as soon as
the solvent is added to minimize volatilization.
(C) GC conditions. The typical operating
conditions for the gas chromatograph are:
(I)
50 ml/min (60 psig) nitrogen carrier gas flow.
(II) 65 ml/min (24 psig) hydrogen gas flow
to detector.
(III) 500 ml/min (50
psig) air flow to detector.
(IV)
235°C injector temperature.
(V)
255°C manifold temperature (detector).
(VI) 155°C column temperature.
(D) Injection. The first step in
the analysis is the injection of the sample into the gas chromatograph. To
eliminate difficulties arising from blowback or distillation within the syringe
needle, one should employ the solvent flush injection technique. The
10-microliter syringe is first flushed with solvent several times to wet the
barrel and plunger. Three micro-liters of solvent are drawn into the syringe to
increase the accuracy and reproducibility of the injected sample volume. The
needle is removed from the solvent, and the plunger is pulled back about 0.2
microliter to separate the solvent flush from the sample with a pocket of air
to be used as a marker. The needle is then immersed in the sample, and a five
micro-liter aliquot is withdrawn, taking into consideration the volume of the
needle, since the sample in the needle will be completely injected. After the
needle is removed from the sample and prior to injection, the plunger is pulled
back 1.2 microliters to minimize evaporation of the sample from the tip of the
needle. Observe that the sample occupies 4.9-5.0 microliters in the barrel of
the syringe. Duplicate injections of each sample and standard should be made.
No more than a 3 percent difference in area is to be expected. An automatic
sample injector can be used if it is shown to give reproducibility at least as
good as the solvent flush method.
(E)
Measurement of area. The area of the sample peak is measured by
an electronic integrator or some other suitable form of area measurement, and
preliminary results are read from a standard curve prepared as discussed
below.
(v)
Determination of desorption efficiency.
(A)
Importance of determination. The desorption efficiency of a particular compound
can vary from one laboratory to another and also from one batch of charcoal to
another. Thus, it is necessary to determine at least once the percentage of the
specific compound that is removed in the desorption process, provided the same
batch of charcoal is used.
(B)
Procedure for determining desorption efficiency.
(I)
Activated charcoal equivalent to the amount in the first section
of the sampling tube (100 mg) is measured into a 2.5 in., 4 mm I.D. glass tube,
flame sealed at one end. This charcoal must be from the same batch as that used
in obtaining the samples and can be obtained from unused charcoal tubes. The
open end is capped with Parafilm. A known amount of hexane solution of
acrylonitrile containing 0.239 g/ml is injected directly into the activated
charcoal with a microliter syringe, and tube is capped with more Parafilm. When
using an automatic sample injector, the sample injector vials, capped with
Teflon-faced septa, may be used in place of the glass tube.
(II) The amount injected is equivalent to
that present in a twenty-liter air sample at the selected level.
(III) Six tubes at each of three levels
(0.5X, 1X, and 2X of the standard) are prepared in this manner and allowed to
stand for at least overnight to ensure complete adsorption of the analyte onto
the charcoal. These tubes are referred to as the sample. A parallel blank tube
should be treated in the same manner except that no sample is added to it. The
sample and blank tubes are desorbed and analyzed in exactly the same manner as
the sampling tube described in (h)(iv) of this subsection
(IV) Two or three standards are prepared by
injecting the same volume of compound into 1.0 ml of methanol with the same
syringe used in the preparation of the samples. These are analyzed with the
samples.
(V) The desorption
efficiency (D.E.) equals the average weight in mg recovered from the tube
divided by the weight in mg added to the tube, or
D.E. =
|
Average weight recovered (mg)
---------------
weight added (mg)
|
(VI)
The desorption efficiency is dependent on the amount of analyte
collected on the charcoal. Plot the desorption efficiency versus weight of
analyte found. This curve is used in (j)(iv) of this subsection to correct for
adsorption losses.
(i) Calibration and standards. It is
convenient to express concentration of standards in terms of mg/1.0 ml
methanol, because samples are desorbed in this amount of methanol. The density
of the analyte is used to convert mg into microliters for easy measurement with
a microliter syringe. A series of standards, varying in concentration over the
range of interest, is prepared and analyzed under the same GC conditions and
during the same time period as the unknown samples. Curves are established by
plotting concentration in mg/1.0 ml versus peak area.
Note: |
Since no internal standard is used in the method,
standard solutions must be analyzed at the same time that the sample analysis
is done. This will minimize the effect of known day-to-day variations and
variations during the same day of the FID response. |
(j)
Calculations.
(i) Read the weight, in mg,
corresponding to each peak area from the standard curve. No volume corrections
are needed, because the standard curve is based on mg/1.0 ml methanol and the
volume of sample injected is identical to the volume of the standards
injected.
(ii) Corrections for the
bank must be made for each sample.
Where:
|
mg sample = mg found in front section of sample
tube.
|
mg sample = mg found in front section of blank
tube.
|
Note: |
A similar procedure is followed for the backup sections.
|
(iii)
Add the weights found in the front and backup sections to get the
total weight in the sample.
(iv)
Read the desorption efficiency from the curve (reference (h)(v)(B) of this
subsection) for the amount found in the front section. Divide the total weight
by this desorption efficiency to obtain the corrected mg/sample.
Corrected mg/sample =
|
Total
weight
----
D.E.
|
|
(v)
The concentration of the analyte in the air sampled can be expressed in mg/cu
m.
mg/cu m = Corrected mg (see (j)(iv)) x
|
1,000 (liter/cu m)
--------------
air volume sampled (liter)
|
(vi)
Another method of expressing concentration is ppm.
ppm = mg/cu m X 24.45/M.W. X 760/P X T +
273/298
|
Where:
|
P = Pressure (mm Hg) of air sampled.
|
T = Temperature (°C) of air sampled.
|
24.45 = Molar volume (liter/mole) at 25°C and
760 mm Hg.
|
M.W. = Molecular weight (g/mole) of analyte.
|
760 = Standard pressure (mm Hg).
|
298 = Standard temperature (°K).
|
(k)
References.
(i) White, L. D.
et al., "A Convenient Optimized Method for the Analysis of Selected Solvent
Vapors in the Industrial Atmosphere," Amer. Ind. Hyg. Assoc. J., 31:225
(1970).
(ii) Documentation of
NIOSH Validation Tests, NIOSH Contract No. CDC-99-74-45.
(iii) Final Report, NIOSH Contract
HSM-99-71-31, "Personal Sampler Pump for Charcoal Tubes," September 15,
1972.
(8) OSHA Laboratory Modification of NIOSH
Method S-156.
(a) Analyte:
Acrylonitrile.
(b) Matrix:
Air.
(c) Procedure: Adsorption on
charcoal, desorption with methanol, GC.
(d)
Principle of the method (subsection (1)(a) of this section).
(i) A known volume of air is drawn through a
charcoal tube to trap the organic vapors present.
(ii) The charcoal in the tube is transferred
to a small, stoppered sample vial, and the analyte is desorbed with
methanol.
(iii) An aliquot of the
desorbed sample is injected into a gas chromatograph.
(iv) The area of the resulting peak is
determined and compared with areas obtained for standards.
(e) Advantages and disadvantages of the
method.
(i) The sampling device is small,
portable, and involves no liquids. Interferences are minimal, and most of those
which do occur can be eliminated by altering chromatographic conditions. The
tubes are analyzed by means of a quick, instrumental method.
(ii) This method may not be adequate for the
simultaneous analysis of two or more substances.
(iii) The amount of sample which can be
taken is limited by the number of milligrams that the tube will hold before
overloading. When the sample value obtained for the backup section of the
charcoal tube exceeds 25 percent of that found on the front section, the
possibility of sample loss exists.
(iv)
The precision of the method is limited by the reproducibility of
the pressure drop across the tubes. This drop will affect the flow rate and
cause the volume to be imprecise, because the pump is usually calibrated for
one tube only.
(f)
Apparatus.
(i) A calibrated personal
sampling pump whose flow can be determined within ±5 percent at the
recommended flow rate.
(ii)
Charcoal tubes: Glass tube with both ends flame sealed, 7 cm long with a 6 mm
O.D. and a 4 mm I.D., containing 2 sections of 20/40 mesh activated charcoal
separated by a 2 mm portion of urethane foam. The activated charcoal is
prepared from coconut shells and is fired at 600°C prior to packing. The
absorbing section contains 100 mg of charcoal, the back-up section 50 mg. A 3
mm portion of urethane foam is placed between the outlet end of the tube and
the back-up section. A plug of silicated glass wool is placed in front of the
adsorbing section. The pressure drop across the tube must be less than one inch
of mercury at a flow rate of 1 liter per minute.
(iii) Gas chromatograph equipped with a
nitrogen phosphorus detector.
(iv)
Column (10 ft × 1/8 in stainless steel) packed with 100/120 Supelcoport
coated with 10 percent SP 1000.
(v)
An electronic integrator or some other suitable method for
measuring peak area.
(vi)
Two-milliliter sample vials with Teflon-lined caps.
(vii) Microliter syringes: 10 microliter,
and other convenient sizes for making standards.
(viii) Pipets: 1.0 ml delivery
pipets.
(ix) Volumetric flasks:
Convenient sizes for making standard solutions.
(g) Reagents.
(i)
Chromatographic quality methanol.
(ii) Acrylonitrile, reagent grade.
(iii) Filtered compressed air.
(iv) Purified hydrogen.
(v) Purified helium.
(h) Procedure.
(i)
Cleaning of equipment. All glassware used for the laboratory
analysis should be properly cleaned and free of organics which could interfere
in the analysis.
(ii) Calibration
of personal pumps. Each pump must be calibrated with a representative charcoal
tube in the line.
(iii) Collection
and shipping of samples.
(A) Immediately
before sampling, break the ends of the tube to provide an opening at least
one-half the internal diameter of the tube (2 mm).
(B) The smaller section of the charcoal is
used as the backup and should be placed nearest the sampling pump.
(C) The charcoal should be placed in a
vertical position during sampling to minimize channeling through the
charcoal.
(D) Air being sampled
should not be passed through any hose or tubing before entering the charcoal
tube.
(E) A sample size of 20
liters is recommended. Sample at a flow rate of approximately 0.2 liters per
minute. The flow rate should be known with an accuracy of at least ±5
percent.
(F) The temperature and
pressure of the atmosphere being sampled should be recorded.
(G) The charcoal tubes should be capped with
the supplied plastic caps immediately after sampling. Rubber caps should not be
used.
(H) Submit at least one
blank tube (a charcoal tube subjected to the same handling procedures, without
having any air drawn through it) with each set of samples.
(I) Take necessary shipping and packing
precautions to minimize breakage of samples.
(iv) Analysis of samples.
(A) Preparation of samples. In preparation
for analysis, each charcoal tube is scored with a file in front of the first
section of charcoal and broken open. The glass wool is removed and discarded.
The charcoal in the first (larger) section is transferred to a 2 ml vial. The
separating section of foam is removed and discarded; the section is transferred
to another capped vial. These two sections are analyzed separately.
(B) Desorption of samples. Prior to
analysis, 1.0 ml of methanol is pipetted into each sample container. Desorption
should be done for 30 minutes in an ultrasonic bath. The sample vials are
recapped as soon as the solvent is added.
(C)
GC conditions. The typical operating conditions for the gas
chromatograph are:
(I) 30 ml/min (60 psig)
helium carrier gas flow.
(II) 3.0
ml/min (30 psig) hydrogen gas flow to detector.
(III) 50 ml/min (60 psig) air flow to
detector.
(IV) 200°C injector
temperature.
(V) 200°C
dejector temperature.
(VI)
100°C column temperature.
(D)
Injection. Solvent flush technique or equivalent.
(E) Measurement of area. The area of the
sample peak is measured by an electronic integator or some other suitable form
of area measurement, and preliminary results are read from a standard curve
prepared as discussed below.
(v)
Determination of desorption efficiency.
(A)
Importance of determination. The desorption efficiency of a
particular compound can vary from one laboratory to another and also from one
batch of charcoal to another. Thus, it is necessary to determine, at least
once, the percentage of the specific compound that is removed in the desorption
process, provided the same batch of charcoal is used.
(B) Procedure for determining desorption
efficiency. The reference portion of the charcoal tube is removed. To the
remaining portion, amounts representing 0.5X, 1X, and 2X (X represents TLV)
based on a 20 l air sample are injected onto several tubes at each level.
Dilutions of acrylonitrile with methanol are made to allow injection of
measurable quantities. These tubes are then allowed to equilibrate at least
overnight. Following equilibration they are analyzed following the same
procedure as the samples. A curve of the desorption efficiency (amt
recovered/amt added) is plotted versus amount of analyte found. This curve is
used to correct for adsorption losses.
(i) Calibration and standards. A series of
standards, varying in concentration over the range of interest, is prepared and
analyzed under the same GC conditions and during the same time period as the
unknown samples. Curves are prepared by plotting concentration versus peak
area.
Note: |
Since no internal standard is used in the method,
standard solutions must be analyzed at the same time that the sample analysis
is done. This will minimize the effect of known day-to-day variations and
variations during the same day of the NPD response. Multiple injections are
necessary. |
(j)
Calculations. Read the weight, corresponding to each peak area from the
standard curve, correct for the blank, correct for the desorption efficiency,
and make necessary air volume corrections.
(k)
Reference. NIOSH Method S-156.