U.S. patent number 4,459,266 [Application Number 06/337,259] was granted by the patent office on 1984-07-10 for air purity monitoring system.
Invention is credited to Charles L. Lamoreaux.
United States Patent |
4,459,266 |
Lamoreaux |
July 10, 1984 |
Air purity monitoring system
Abstract
A system for detecting specific contaminants in a gas such as
compressed air and automatically indicating the degree of detected
contamination. The system is selectively operable in either a PURGE
mode or a TEST mode. During the PURGE mode, air flow rate is
adjusted to a selected level by reference to a flow indicator. The
system includes automatic timing control, operable in the TEST
mode, to cause an air sample of prescribed volume to flow through a
detection chamber. The system uses commercially available detector
tubes which are specific to the particular contaminant suspected
and which provide a positive indication of the degree of detected
contamination for the volume of air in the sample. The system
performs automatically in response to the operation of selected
switches in a prescribed sequence, without any need for instrument
calibration, thus permitting its use by virtually anyone inclined
to use it. It is light and thereby portable, thus permitting it to
be used in almost any location or under any conditions where
compressed air for respiratory use is provided.
Inventors: |
Lamoreaux; Charles L. (Rancho
Palos Verdes, CA) |
Family
ID: |
23319791 |
Appl.
No.: |
06/337,259 |
Filed: |
January 5, 1982 |
Current U.S.
Class: |
422/86;
128/204.22; 422/88; 600/532 |
Current CPC
Class: |
G01N
31/223 (20130101); G01N 2001/2297 (20130101); G01N
2001/2238 (20130101) |
Current International
Class: |
G01N
31/22 (20060101); G01N 33/00 (20060101); G01N
1/22 (20060101); G01N 031/06 (); G01N 031/22 () |
Field of
Search: |
;128/719,204.22 ;73/23
;422/84,85,86,88 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Marcus; Michael S.
Attorney, Agent or Firm: Bissell; Henry M.
Claims
What is claimed is:
1. A portable air purity monitoring system for monitoring
compressed air for respiratory use comprising:
a housing having an exterior face;
a first, flow meter, chamber and a second, detector tube, test
chamber mounted in operative position on said face;
means defining an air passage through the system including said
first and second chambers in series between inlet and exhaust
ports, the exhaust port exhausting to atmosphere, said means
including a first valve remotely controllable between open and
closed positions to control air flow through said passage and means
for coupling the inlet portion to a source of high pressure
compressed air;
a pressure regulator connected in series with the air passage
adjacent the inlet port for reducing the pressure of compressed air
applied at the inlet port to a predetermined level slightly above
atmospheric pressure;
means for operating said system in a PURGE mode to clear the air
passage of prior art samples;
means coupled in series with the air passage for adjusting the rate
of flow through said air passage during the PURGE mode, including a
manually operable flow control valve mounted adjacent said first
chamber; and
means for operating said system in a TEST mode, including means for
retaining a preselected detector tube within the detector tube test
chamber coupled in series with the air passage adjacent the exhaust
port and further including an automatic timer located within the
housing and coupled to remotely control the first valve, the timer
being preset to determine different, alternatively selectable, time
intervals for the flow of air through said air passage in order to
cause a predetermined sample of air corresponding to the test being
run to flow through the detector tube during the TEST mode
operating interval.
2. The system of claim 1 further including means mounted along said
exterior face for separately storing a plurality of different
detector tubes integrally in said housing and segregated by
type.
3. The system of claim 1 wherein both the PURGE mode operating
means and the TEST mode operating means include means for
controlling the first valve between open and closed positions.
4. The system of claim 3, wherein the first valve is solenoid
actuated, including solenoid control means coupled to control the
application of an actuating potential to the valve solenoid.
5. The system of claim 4 wherein the PURGE mode operating means
includes switches coupled to the solenoid control means for
selectively controlling the opening or closing of the first
valve.
6. The system of claim 4 wherein the automatic timer is coupled to
the solenoid control means and is operable to maintain the first
valve open during the TEST mode interval, said timer having a
plurality of preset time intervals selectable by an operator.
7. The system of claim 6 wherein the TEST mode operating means
further includes a plurality of switches coupled to activate the
timer for different selectable TEST mode time intervals.
8. An air purity monitoring system for monitoring compressed air
for respiratory use comprising:
a housing having an external mounting panel;
means defining an air passage through the system between an inlet
coupling for coupling to a high pressure source of compressed air
and an exhaust port which exhausts to atmosphere;
a pressure regulator coupled in the air passage adjacent the inlet
coupling for reducing the pressure of compressed air from said
source to a predetermined level slightly above atmosphere
pressure;
a first valve in series with the air passage, said valve being
remotely controllable from the external panel;
a manually controllable second valve in series in the air passage
for controlling flow rate therethrough;
a flow meter serially mounted in the air passage and calibrated to
indicate rate of air flow through the air passage;
a detector tube test chamber coupled in series in the air passage
for mounting a detector tube to receive air flowing through the air
passage prior to exhausting through the exhaust port;
a plurality of switches coupled to control the first valve in a
PURGE mode and in a TEST mode, respectively, said switches
including at least two test switches for selectively actuating the
first valve for different preselected time intervals in testing for
different contaminants;
wherein the flow meter, the detector tube test chamber, the second
valve, and the plurality of switches are mounted on an exterior
face of the mounting panel in positions accessible from the
exterior of the housing and the second valve is integrally mounted
in an assembly containing the flow meter.
9. The system of claim 8 wherein the plurality of switches includes
a purge switch for effecting the opening of the first valve in the
PURGE mode and a stop switch for selectively closing the first
valve after a preselected interval to terminate the PURGE mode.
10. The system of claim 8 wherein the flow meter comprises a
vertically oriented transparent tube having a pair of balls
therein, said balls being movable differentially against gravity by
the force of air flow to provide different indications of air flow
rate, and first and second calibration markers positioned along
said tube, the first marker being effective with one of said balls
to indicate a first selected flow rate and the second marker being
effective with the other ball to indicate a second selected flow
rate different from the first selected rate.
11. The system of claim 8 wherein the detector tube test chamber
includes the exhaust port at one end and further comprises a
closure member spaced from the exhaust port end, said closure
member being removable from the chamber and having means for
sealingly receiving one end of an elongated detector tube.
12. The system of claim 11 wherein the closure member includes an
external knob for use in threading the member in and out of an
engaged position in the detector tube test chamber, a central bore
having an internal O-ring for sealingly engaging a detector tube,
and an air passage extending between the central bore and the
external circumferential surface of the closure member.
13. The system of claim 12 wherein the detector tube test chamber
includes an air passage extending through a side wall thereof to
communicate with the air passage of the closure member when the
closure member is in position within the detector tube test
chamber.
14. The system of claim 13 further including means defining a
closed space between the air passages of the closure member and the
detector tube test chamber when the closure member is in position
therein, said means including a pair of O-rings encircling the
closure member for sealing said space.
15. The system of claim 11 wherein the exhaust port end of the
detector tube test chamber is shaped to receive one end of a
detector tube and retain the tube in position in sealing engagement
with the closure member.
16. The system of claim 12 wherein the closure member includes a
central bore having portions of different diameter, each portion
having a corresponding O-ring seal, for receiving detector tubes of
different sizes.
17. The system of claim 12 wherein the closure knob defines a
central tapered recess in the upper face thereof to facilitate
breaking open the ends of a detector tube in preparation for
use.
18. The system of claim 13 further including means connecting the
outlet end of the flow meter to the air passage of the detector
tube test chamber.
19. The system of claim 8 further including a timer being operable
to control the timing of at least two, distinct, alternatively
selectable, time intervals.
20. The system of claim 19 wherein one of the test switches is
coupled to the timer to select a first one of said time intervals
and another of the test switches is coupled to the timer to select
another one of said time intervals, and means coupling the timer to
the first valve for remotely controlling the position thereof to
permit a predetermined volume of air to flow through a detector
tube in the detector tube test chamber during a contaminant
test.
21. The system of claim 19 wherein the plurality of switches and
the timer are mounted in a unit which is readily removable from the
front panel for modification and replacement thereof.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention is directed to monitoring the contaminant
concentration in gases. More particularly, the present invention is
directed to monitoring concentrations of selected contaminants in
compressed air for respiratory use.
2. Description of the Prior Art
Many systems have been devised and are in use for determining
contaminant concentrations in gases. Such systems often include
pumps to meter a specified amount of gas through a testing material
which changes color upon contact with a particular contaminant.
These systems generally require a vial, which is inserted into the
testing unit. A read-out is obtained from the vial which may be
directly or indirectly used to determine the contaminant presence
or concentration. Examples of such systems and the vials used as
detector tubes are disclosed in a certain products bulletin of
National Draeger, Inc., entitled "Gas and Vapor Detection
Products".
Other systems in use in industry include in-line process sensors
which determine a change in a characteristic of a gas being tested
which is indicative of a change in contaminant concentration. These
types of systems are useful where the contaminant itself is colored
and, thus, changes in light reflection or transparency can be used
to determine concentrations.
In other systems, electrical properties such as resistance or
conductivity are measured against a standard to determine a
concentration of the contaminant. Such prior art systems generally
function quite well in the areas of suggested use. However, there
is a need in the art for a system which is easily adaptable for use
in measuring contaminant concentrations in compressed air and which
can be used reliably by persons without particular skill or
training in the use of air monitoring systems. It is apparent that
with regard to compressed air which is used for breathing, for
instance, the water vapor, oil, carbon monoxide, and carbon dioxide
content of the compressed air should be monitored since the
presence of such contaminants in even small amounts can be
detrimental to the user. Thus, the present invention is directed to
a system which can be easily utilized and will accurately test
compressed air for the presence of various contaminants.
SUMMARY OF THE INVENTION
In brief, arrangements in accordance with the present invention
constitute a system for detecting and measuring the concentrations
of contaminants in compressed air. Such systems utilize particular
contaminant indicators, known in the prior art, in the form of
sealed glass tubes containing materials responsive to the presence
of a particular contaminant. One suitable type of detector tube is
available from National Draeger, Inc., 401 Parkway View Drive,
Pittsburgh, Pa. Prior to use in arrangements of the present
invention, the tips of the tubes are broken off to prepare the
tubes for use.
Arrangements in accordance with the present invention comprise a
housing containing the various air passages, valves and control
circuitry and including a front face or panel on which are mounted
a pair of air flow chambers having means for providing indications
of flow rate and contamination, respectively, together with a
plurality of control switches. A first one of the flow chambers
includes a flow control valve having a knob accessible to the user
and a standard flow meter for adjusting and indicating flow rate.
The other flow chamber constitutes a test chamber having a closure
member with a knob accessible to the user and designed to mount a
standard detector tube in position to receive a preselected volume
of air directed through the tube as an air sample and to provide an
indication of contamination to the user. Automatic timing means,
controllable for preselected distinct time intervals by one of the
push button switches on the front of the panel, serves to control
the air flow through the detector tube. Other front panel switches
provide for purging the air system in accordance with operating
instructions in preparation for contaminant monitoring.
The internal circuitry of the instrument includes a solenoid
actuated valve for controlling air flow through the instrument and
associated solenoid control circuitry equipped to apply an
actuating voltage to the valve solenoid. The solenoid control
circuitry includes a timer stage and respective "purge" and "stop"
switches on the front panel. The timer may be activated to develop
different preselected time intervals upon the closure of one or
another of the test selector switches on the front panel .
BRIEF DESCRIPTION OF THE DRAWINGS
A better understanding of the present invention may be had from a
consideration of the following detailed description, taken in
conjunction with the accompanying drawings in which:
FIG. 1 is a perspective view of a monitoring system in accordance
with the present invention;
FIG. 2 is a sectional view of a portion of the monitoring system,
taken along the line 2--2 of FIG. 1;
FIG. 3 is a sectional view of another portion of the monitoring
system, taken along the line 3--3 of FIG. 1; and
FIG. 4 is a block diagram of the control circuitry and airflow
system of the embodiment of FIG. 1.
DESCRIPTION OF THE PREFERRED EMBODIMENT
As best shown in FIG. 1, the preferred embodiment of the air
monitoring system 10 comprises a housing 12 having a handle 14, a
front face 16 and couplings or connections (not shown) at the rear
for attachment to pressure lines or hoses and to an electrical
power source (typically 110 or 220 volts AC). By means of the air
line coupling, the system 10 may be used with equal facility for
determining the concentration of selected contaminants in
compressed air from a compressor, from an accumulator or storage
system, and from individual self-contained breathing apparatus
(SCBA) bottles or other compressed air cylinders, merely by
selection of appropriate adapters and fittings. The front face 16
mounts a flow meter assembly 20 and a detector tube test chamber
assembly 22 with a detector tube 23 therein, together with a
control module 24, shown as including a switch assembly 26 and
associated sub-panel 28 bearing on its front face an instruction
label 30. Below the control assembly 24 is positioned a storage
module 32 having a plurality of storage containers 34 for up to 40
detector tubes ready for use in the contamination monitoring
function. The system 10 is of extremely compact and convenient
design, being a cube of 7 inches on a side and weighing eight
pounds, thus being completely portable and ready to use at any time
or place where 110 volt power is available or, in the alternative,
by use of internal 12 volt battery power, which is optional.
Referring to FIG. 2 for details of the flow meter assembly 20, the
assembly is shown comprising a chamber 36 enclosed by a clear
plastic cover 38 extending between upper and lower support blocks
40 and 42 mounted on the front face 16. The lower support block 42
includes a rotary, cartridge type, valve 44 having a central
cylindrical member 46 to which is attached an external knob 48. The
member 46 is mounted for rotation within a cylindrical chamber 50,
sealed by O-rings 52 and having a central bore communicating with
an inlet air passage 54 and, with the valve 44 in the open
position, as shown in FIG. 2, with a passage 56 leading to a flow
meter 60. The flow meter comprises a tube 62 extending between the
upper and lower blocks 40, 42, and sealingly mounted thereto by
O-ring seals 64 at the opposite ends of the tube 62. The flow meter
tube 62 is of glass and is calibrated with dual scales: 0-200
cc/min. and 0-2000 cc/min. Near the upper end of the tube a silver
marker 70 is placed on the glass at the calibration mark
corresponding to 2.0 liters per minute. About mid way of the tube
62 a black marker 72 is located at a calibration mark indicating
0.2 liters per minute of air flow through the tube. The flow meter
60 further includes a pair of balls shown at the bottom of the tube
62, a black ball 74 and a silver ball 76. These are to simplify the
setting of the air flow by means of the control valve 44 at a given
selected air flow rate.
Shown in place within the upper support block 40 is a closure
member 80, threadably mounted within the block 40 by mating threads
82. A port extends from the flow meter tube 62 through a central
bore of the closure member 80 and communicates with an air passage
84 extending through the front panel 16. This air passage is sealed
about the periphery of the closure member 80 by upper O-ring 86 and
the adjacent O-ring 64. An Allen screw slot is shown at 88.
Referring to FIG. 3, the detector tube test chamber assembly 22 is
shown comprising upper and lower support block 90, 92. Threadably
mounted within the upper block 90 is a closure member 94 having a
knob 95, a central bore 96 and internal air passage 98
communicating with external air passage 100 which is connected
within the instrument to the passage 84 of FIG. 2. The closure knob
95 includes a central recess 115 provided to facilitate breaking
the tips off a detector tube prior to use. There is a cylindrical
space 102 between the outer surface of the closure member 94 and
the inner face of the bore of support member 90, to insure
communication for air flow between the passages 98 and 100 without
regard to the rotational position of the closure member 94. This
space 102 is sealed by upper and lower O-rings 104, 106.
Within the bore 96, O-rings 110 and 111 are positioned for the
purpose of sealingly engaging a detector tube 23 when it is placed
in position within the bore 96, thus sealing the upper end of the
detector tube to the space within the upper part of the bore 96 and
communicating with the air passage 98. The two O-rings are provided
to accommodate different sizes of detector tubes.
The lower support block 92 contains an exhaust port 112 extending
to atmosphere and having a cone or funnel-shaped portion 114 facing
upward within the block 92. This funnel-shaped portion 114 is for
the purpose of receiving the lower end of the detector tube when it
is placed in the chamber 116 and retain it in sealing engagement
within the bore 96 during a test. The chamber 116 is encased by a
clear plastic cover 118 extending between the upper and lower
support blocks 90, 92.
The block diagram of FIG. 4 shows the operative elements of the
monitoring system 10. The air flow passage is shown as comprising a
coupling 130 for coupling to a high or low pressure air source and
providing the compressed air to a pressure regulator 132 which
reduces the pressure to a level suitable for use in the instrument.
Usually this pressure will be slightly above atmospheric pressure
at sea level. Connected to the output of the pressure regulator 132
is a solenoid-controlled valve 134 comprising an air valve 136 and
associated solenoid actuator 138. The solenoid actuator 138 is
operable by 12 volts DC. From the valve 136, the air passage
extends to the flow control valve 44 of the flow indicator assembly
(see FIG. 2) and thence, by interconnected air passages 84, 100, to
the detector tube test chamber assembly 22 (see FIG. 3); thereafter
to exhaust to atmosphere through port 112.
The control assembly 24 is a replaceable module which can be
readily removed from the system 10 and replaced by another one
adapted to timing the air flow for different intervals to permit
monitoring the presence of a wide variety of contaminants in
compressed air. As shown in the block diagram of FIG. 4, the
control assembly 24 includes a switch assembly 26, a timer 140 and
a solenoid control stage 142. The switch assembly 26 is shown
comprising a plurality of individual switches: a purge switch 144,
a stop switch 146, and timer select switches 148, 149 (labelled A
and B to indicate difference in timing interval for different
contaminant tests).
The solenoid control stage 142 is operative, in response to inputs
from the timer stage 140 or the purge switch 144 of stop switch
146, to selectively apply 12 volts DC to the solenoid actuator 138,
thereby opening and closing the valve 136. 12 volts DC from a power
supply 147 is also applied to the switches of the switch assembly
26 and thence to the timer 140 and/or solenoid control stage 142 by
the closure of selected switches. Each of the switches 144, 146,
148 and 149 is of the type which contains self-illuminated means
which is activated when the switch is pressed. The timer 140 and
solenoid control stage 142 are solid state modules, known in the
art--"chips" in the current vernacular--which can be readily
replaced, particularly with respect to the timer 140 which may be
easily changed within a given assembly 24 if it is desired to equip
the assembly 24 with different timing ranges for different
contaminants. A programable solid state timer can also be used,
controllable from the front panel for example, for infinite
variability.
It will be understood that the 12 volts DC may be obtained from an
external source, if available, or from a self-contained battery
pack if desired, rather than by conversion through the power supply
147 from the 110 volt AC input as shown.
Operation of the System
In describing the operation of the system 10 in the testing of
compressed air for contaminants, it will be assumed that the
function A of switch 148 is for the testing of either carbon
monoxide or carbon dioxide and the function B of switch 149 is for
the testing of either water or oil vapor. The selection of the test
for either carbon monoxide or carbon dioxide is determined by the
selection of the appropriate detector tube 23 for insertion in the
detector tube test chamber assembly 22; the time duration of air
flow is the same for both contaminants. Similarly, the selection
for testing for water or oil vapor is determined by the selection
of an appropriate detector tube 23, the time interval being the
same for both vapors.
Each detector tube of the standard Draeger type is of the same
configuration, being of slender hollow glass construction with a
calibrated scale and an arrow for indicating flow direction thereon
and containing a suitable test material. The hollow glass tube is
sealed at both ends by tips which are to be broken off just prior
to use by insertion in the recess 115 of the closure knob 95 and
tilting until fracture.
The system of the invention is operated in one of two selectable
modes, a PURGE mode and a TEST mode. In the PURGE mode, the purge
switch 144 is pressed and the air flow rate is adjusted by means of
the flow control valve 44 as determined by the flow meter 60.
Purging is done without any detector tube 23 within the detector
tube test chamber assembly 22 and continues for a time interval
timed by the operator. This time interval is not critical and need
not be precisely timed. At the end of the PURGE interval, the stop
switch 146 is pressed to terminate the air flow.
The closure member 94 of the test chamber 116 is then removed by
turning the knob 95 counterclockwise. An appropriate detector tube
23 is selected and both tips are broken off by bending them after
insertion in the recess 115 of the closure knob 95. The upper end
of the thus-opened detector tube 23 is then inserted within the
bore 96, flow arrow pointing down, away from the closure, where it
is retained by the O-ring 110 or 111. The numbers of the scale on
the tube 23 are aligned with a line (not shown) on the closure knob
95. Thereafter the closure member and detector tube 23 are inserted
into the test chamber 116 and the knob is tightened approximately
one turn with the line facing outwardly so that the scale on the
detector tube 23 is visible through the cover 118 on the front of
the assembly, as shown in FIG. 1. The system 10 is now ready for
testing the air for the selected contaminant.
In the TEST mode, the appropriate test switch 148 or 149 is
pressed. This illuminates its face to indicate the selected test is
in process and the timer 140 becomes operative, through the
solenoid control stage 142, to maintain the valve 136 open for the
precise time interval corresponding to the selected test. The flow
rate with the detector tube 23 installed will be slightly less than
the rate which was set during the PURGE mode interval. This is
normal and should not be readjusted. To obtain a reading on the
detector tube 23, it may be necessary to repeat the test by pushing
the same test button and interpreting the resulting indication on
the detector tube to allow for test repetition.
Example: Carbon Monoxide Test
Assuming the compressed air is to be tested for carbon monoxide,
the PURGE switch 144 is pressed and air flow is adjusted until The
black ball 74 (FIG. 2) is aligned with the black indicator mark 72.
The stop switch 146 is pressed to terminate purging after
approximately one minute. The air flow rate will have been adjusted
to equal 0.2 liters per minute.
A carbon monoxide detector tube is then selected, prepared as
described above and placed within the chamber 116. The switch 148
is then pressed to initiate the TEST mode. The timer 140 will
permit precisely one liter to flow through the tube in the preset
five-minute interval and will automatically close the valve 136 at
the end of the test interval. If carbon monoxide is present, the
white indicator chemical in the detector tube 23 will change color
to a brownish-green. The total length of the discoloration is a
measure of the contamination in PPM (parts per million). The parts
per million are read directly on the detector tube and this reading
is compared with a reference figure of maximum allowable parts per
million of carbon monoxide contamination as established by the
appropriate agencies (U.S. Navy, O.S.H.A., California, etc.). If no
reading is obtained during the first test, the test can be
immediately repeated and the indication from extent of
discoloration divided in two. However, one should not save a
detector tube for use in a subsequent test, even if the results in
the initial test are negative.
Example: Carbon Dioxide Test
In testing for carbon dioxide, exactly the same procedure is
followed as for carbon dioxide, except that a different (carbon
dioxide) detector tube 23 is used. If carbon dioxide is present,
the chemical in the detector tube changes from white to violet.
Example: Water Vapor Test
In testing for water vapor, the system is operated in the PURGE
mode for approximately five minutes on any new installation or
hookup and for approximately two minutes on any repeat tests on any
one hookup. Air flow is adjusted to a rate of 2.0 liters per minute
by aligning the silver ball 76 with the silver marker 70 (see FIG.
2). It will be understood, of course, that the balls 74, 76 are
forced upwardly in the tube 62 in accordance with the rate of air
flow upwardly through the tube.
Following termination of the PURGE mode, a detector tube containing
a material specific to testing for water vapor is opened and
inserted within the test chamber as previously described.
Thereafter, the test switch 149 (function B for water vapor or oil
vapor) is pressed. Responsive to switch 149, the timer 140
maintains the valve 136 open for a preset time period of 12.5
minutes, during which 25 liters of air flow through the detector
tube. To obtain an indication, it may be necessary to repeat the
TEST mode for from two to four test periods. If the air sample
contains water vapor, the indicator material within the detector
tube 23 will turn from reddish brown to greenish gray. Again, the
total length of the discoloration within the tube is a measure of
the contamination, and the concentration in milligrams per cubic
meter can be read directly from the tube. Other equivalents (PPM,
dew point, etc.) may be obtained from a reference chart.
Example: Oil Vapor Test
In testing for the presence of oil vapor, a suitable detector tube
is selected and the purging and testing are conducted in the same
fashion as in testing for water vapor (the same timer control
switch 149 is pressed) with the following exception. After the test
period(s) is concluded, the detector tube 23 is removed from the
chamber, is bent at a breaking point (marked on the glass with two
dots) so that the outer glass tube and inner reagent ampule break.
Care should be exercised, since the ampule contains concentrated
sulfuric acid. The detector tube 23 is then replaced in the test
chamber and air is permitted to flow through the system for about
ten seconds (using the PURGE and STOP switches). This forces the
acid into the indicator chemical where the acid stains the white
indicator chemical yellowish-brown for approximately one-half inch.
Air flow is to be stopped at this point. If the monitored air
sample contains oil vapor, the yellowish-brown stain will discolor
to a blackish tinge in relation to the concentration of oil vapor.
This is compared with a color standard which is included in the
container of oil vapor detector tubes. The actual concentration of
the oil vapor contaminant is then calculated by the following
formula: ##EQU1## The total liters of air equals the number of time
periods times the 25 liters in each test sample. The result of the
calculation may then be compared with the maximum allowable degree
of oil vapor contamination (five micrograms per cubic millimeter as
specified by the agencies mentioned above).
The air monitoring system of the present invention thus provides a
simple, virtually foolproof, reliable means of testing for those
contaminants which are most likely to be encountered in compressed
air, as may be used in self-contained respiratory applications of
scuba divers and fire fighters, for example. The system uses a
specific detector tube for each type of hazardous gas or vapor
which is suspected. These are standard, commercially available
tubes which provide a direct reading of the specific contaminant as
shown by the length or degree of color change. Testing is readily
effected by connecting the system to the air source to be tested,
adjusting the flow rate while purging to that which is specified
for the detector tube selected, and then testing by simply pushing
the appropriate time control switch, which will illuminate. When
the switch illumination goes out, the test is complete, and the
results can be read directly from the tube. The system is accurate,
reliable, inexpensive, easy to operate and can be used virtually
anywhere under any conditions. Because the testing is automatic, no
calibration of an instrument is necessary. The instrument carries
its own supply of 40 detector tubes, which is adequate for extended
use before restocking. Should a fault develop in the control module
or if it is desired to test for other contaminants, it is a simple
matter to replace a given control module with another and
subsequent tests can be conducted by simply selecting the
appropriate detector tubes, of which approximately 100 or more are
listed in the above-referenced bulletin of National Draeger,
Inc.
Although there has been described one particular arrangement of an
air purity monitoring system in accordance with the invention for
the purpose of illustrating the manner in which the invention may
be used to advantage, it wll be appreciated that the invention is
not limited thereto. Accordingly, any and all modifications,
variations or equivalent arrangements which may occur to those
skilled in the art should be considered to be within the scope of
the invention as defined in the annexed claims.
* * * * *