Energizer ATX612 User Manual

Multi-Gas Monitor  
P/N 1706-3421  
REV 03 Printed 0900-2000  
Specifications Subject to Change  
ATX612  
GUARANTEED.  
FOR LIFE.  
1001 Oakdale Road, Oakdale, PA 15071-1500  
(412) 788-4353 • Toll Free 1-800-DETECTS  
FAX 412-788-8353 • Service Dept. 1-888-788-4353  
Instruction  
Manual  
INDUS TRIAL S CIENTIFIC  
CORP ORATION  
Dear Valued Customer,  
Thank you for buying and using Industrial Scientific’s  
Model ATX612 Multi-Gas Monitor.  
Your ATX612 can be relied upon for dependable service,  
day after day. It has been designed, manufactured, tested  
and proven under the most scrutinizing conditions  
possible. With the minimal care and maintenance  
described in this Instruction Manual, it will provide you  
with years of reliable monitoring.  
I am most concerned that you be pleased with the  
performance of your ATX612 in the months and years  
ahead. I urge you to call us with any questions or  
comments you may have. Often times a phone call and a  
question can save you hours of frustration. Please never  
hesitate to contact me at 1-800-DETECTS (338-3287).  
All of us at Industrial Scientific appreciate the opportunity  
to serve you.  
Sincerely,  
Kent D. McElhattan  
President & CEO  
Industrial Scientific Corporation  
1
TABLE OF CONTENTS  
1. WARNINGS AND CAUTIONARY STATEMENTS  
2. UNPACKING THE INSTRUMENT  
3. ATX612 F  
3
4
WARNINGS AND CAUTIONARY STATEMENTS  
1.  
4. INSTRUMENETAOTURES  
PERATION  
4
5
Failure to perform certain procedures or note certain  
conditions may impair the performance of the  
instrument. For maximum safety and performance,  
please read and follow the procedures and conditions  
outlined below.  
4
.1 Charging the Battery  
5
4.1.1 Alkaline Battery Option  
.2 Turning the ATX612 On and Off  
8
4
8
4.3 Display Backlight  
4.4 Internal Sampling Pump  
4.5 Operating Modes  
4.5.1 Reading  
8
8
9
9
!
Oxygen deficient atmospheres may cause combustible  
4.5.2 Sensor Configuration  
4.5.3 PPM Hydrocarbon  
4.5.4 Zero  
9
9
gas readings to be lower than actual concentrations.  
9
4.5.5 Peak  
9
!
Oxygen enriched atmospheres may cause combustible  
4.5.6 Peak Clear  
10  
10  
10  
10  
10  
10  
10  
10  
10  
11  
11  
11  
11  
12  
12  
12  
15  
15  
16  
17  
17  
17  
17  
18  
18  
18  
18  
18  
18  
18  
18  
19  
19  
20  
20  
20  
20  
21  
21  
21  
22  
22  
22  
23  
gas readings to be higher than actual concentrations.  
4.5.7 Date  
4.5.8 Cal Date  
!
Calibrate the combustible gas sensor after each  
4.5.9 Log Time  
incident where the combustible gas content causes the  
instrument to latch in the OVER-RANGE alarm condition.  
4.5.10 TWA  
4.5.11 STEL  
4.5.12 Hygiene Reset  
4.6 Alarm Indicators  
4.6.1 Low Alarm  
!
Silicone compound vapors may affect the combustible  
gas sensor and cause readings of combustible gas to be  
lower than actual gas concentrations. If the instrument has  
been used in an area where silicone vapors were present,  
always calibrate the instrument before next use to ensure  
accurate measurements.  
4.6.2 High Alarm  
4.6.3 Over-Range Indication  
4.6.4 Combustible Gas Over-Range  
4.6.5 Low Battery Warning  
4.6.6 Battery Failure  
4.6.7 Fault Indication  
5.  
C
ATX612  
6. CAHLAINBGRIANTGING THE  
INSTRUMENT SETTINGS  
!
Sensor openings and water barriers must be kept clean.  
6
.1 Setspan  
Obstruction of the sensor openings and/or contamination  
of the water barriers may cause readings to be lower than  
actual gas concentrations.  
6.2 Alarms  
6.3 Code  
7. HYGIENE/DATALOGGING FUNCTIONS  
7.  
1
Definition of Terms  
7.1.1 Data Log  
7.1.2 Period  
!
Sudden changes in atmospheric pressure may cause  
temporary fluctuations in the oxygen reading.  
7.1.3 Logging Session  
7.1.4 Real Time Clock  
7.1.5 Log Time Clock  
7.1.6 Calendar  
7.1.7 TWA  
7.1.8 STEL  
!
Recharge battery only in a non-hazardous location.  
!
Use the RS-232 port only in a non-hazardous location.  
!
Instrument is tested for intrinsic safety in explosive  
7.2 Principles of Operation  
7.3 Resetting the Hygiene Functions  
7.4 Downloading the ATX612  
8. MAINTENANCE  
gas/air (21% oxygen) mixtures only.  
CAUTION: High Over-Range (+OR) combustible  
!
gas readings may indicate an  
8.1 Cleaning  
8.2 Changing the Battery  
explosive concentration of  
combustible gas.  
8.2.1 Replacing the Nicad Battery Module  
8.2.2 Replacing Alkaline Battery Cells  
8.3 Opening the Instrument for Service  
8.4 Installing or Changing Sensors  
8.4.1 Toxic/Oxygen Sensor Removal/Replacement  
8.4.2 Combustible Sensor Removal/Replacement  
8.5 Changing the Internal Filter  
9. REPLACEMENT PARTS  
10. SPECIFICATIONS  
11. DEFAULT ALARM SETTINGS  
12. ATX612 OPTIONS & ORDERING INFORMATION  
13. WARRANTY  
26  
27  
27  
28  
2
3
• 90 dB audible and ultra-bright visual alarm indicators.  
• Optional external audible or vibrating alarms.  
UNPACKING THE INSTRUMENT  
2.  
3.  
• High and low alarms for combustible and toxic gases;  
enrichment and depletion alarms for oxygen.  
The shipping box should contain the following items.  
Account for each item before discarding the box.  
• User selectable latching alarms.  
QUANTITY PART NUMBER  
DESCRIPTION  
• User selectable access code for security of calibration  
and alarm settings.  
1
1
1
1
1
1810-2707  
1706-3421  
1706-3256  
1810-0628  
1810-3077  
ATX612 Multi-Gas Monitor  
ATX612 Instruction Manual  
Maintenance Tool  
Shoulder Strap  
Charging Adapter  
(with Nicad Battery Only)  
Power Cord  
• Combustible gas OVER-RANGE protection.  
• PEAK reading mode.  
• Press and hold power switch to prevent accidental turn  
ON or turn OFF.  
1
1705-1710  
• Hygiene/Datalogging option that can be installed by the  
factory or the customer, to provide short term exposure  
limit (STEL) and time-weighted average (TWA)  
readings with 110 hours datalogging capacity.  
After unpacking, if any listed item is missing, contact  
either your local distributor of Industrial Scientific products,  
or call Industrial Scientific Corporation at 1-800-DETECTS  
(338-3287) in the United States and Canada, or  
412-788-4353.  
• The ATX612 is classified as intrinsically safe by the  
following agencies:  
ATX612 FEATURES  
- Underwriters Laboratories (UL).  
- Canadian Standards Association (CSA). Canadian  
Standards Association has assessed only the  
combustible gas portion of this instrument for  
performance.  
The Industrial Scientific ATX612 Multi-Gas Monitor may  
be configured to continuously monitor one, two, three or  
four gases in any combination of the following:  
- Mine Safety and Health Administration (MSHA).  
- Workcover Authority, NSW, Australia.  
- Department of Mineral Resource, NSW, Australia.  
- CENELEC (DEMKO)  
• Oxygen  
• Combustible gases (%LEL) or methane (% by volume  
CH4). User selects %LEL or %CH4 prior to calibration.  
• Any two of the following toxic gases:  
Carbon Monoxide  
Hydrogen Sulfide  
Sulfur Dioxide  
Chlorine  
Nitrogen Dioxide  
Chlorine Dioxide  
INSTRUMENT OPERATION  
4.  
4.1 CHARGING THE BATTERY (NICAD BATTERY OPTION)  
If the ATX612 is equipped with a Nicad battery pack, fully  
charge the battery pack before use. A universal charging adapter  
is included with the unit for charging the ATX612 battery pack.  
The battery pack may be charged while attached to the  
instrument or when removed to allow round-the-clock operation  
of the ATX612 using a spare battery.  
• The ATX612 automatically recognizes and displays the  
installed sensors when switched on.  
• One-Button calibration (microprocessor controlled).  
• Built-in pump for remote gas sampling.  
• Backlit display for viewing in low light conditions.  
The ATX612 is equipped with a nickel-cadmium battery pack  
with a built-in “smart” charging system. When plugged into the  
charging adapter, the battery will recharge at a high rate until  
fully charged and then will reduce to a maintenance trickle  
charge rate. The battery will not be damaged if it is left  
connected to the charger for extended periods.  
• Round-the-clock monitoring capability using the  
interchangeable rechargeable nickel-cadmium (Nicad) or  
replaceable alkaline battery packs.  
• Plug-in sensors that can be changed or replaced without  
special tools or soldering equipment.  
4
5
A dead battery will be fully recharged in 4.5 hours. The  
Nicad battery pack has a LED charge status indicator to  
show the current status when connected to the charger.  
The LED indicator has five states as follows:  
Infrared Data Interface  
Pump Exhaust Port  
Charging Socket  
(Nicad Versions)  
• Solid Amber:  
• Solid Green:  
Fast charge in progress  
Fully charged, in trickle  
charge mode  
Battery too hot/cold to be  
fast charged, in trickle  
charge mode  
• Flashing Green:  
Gas Sample Inlet  
Fitting  
• Flashing Amber:  
Instrument running, fast  
charge mode  
• Alternating Green/Amber: Trouble, electrical problem  
in battery pack  
0 0  
21.0 0  
Battery Status  
Indicator  
A fully charged Nicad battery pack will typically operate a  
four-gas configured ATX612 for up to 16 hours. When the  
instrument is in the normal viewing mode, an eight-  
segment battery status indicator continuously displays the  
battery condition. Each segment represents approximately  
2 hours of operating time. When the battery is fully  
discharged, the display will read BATTERY FAIL and the  
instrument will emit a short beep once a second (See  
Section 4.6.6). Turn off the instrument and recharge the  
battery pack when BATTERY FAIL appears.  
Battery Pack  
Hex Screws  
Shoulder Strap/  
Optional Handle  
Attachment  
Figure 2  
WARNING: Recharge Nicad battery pack only in a  
!
non-hazardous location.  
Ultra-bright Visual  
Alarm Light Bar  
%
PPM  
Display  
BATT  
LEL  
OXYGEN  
INDUS TRIAL  
S CIENTIFIC  
ATX6 1 2  
Hidden (-) Key  
Hidden (+) Key  
E
ON/ OFF MODE  
External Alarm Jack  
Enter/Backlight Key  
Alarm Speaker  
On/Off/Mode Key  
Interchangeable Nicad  
or Alkaline Battery  
Pack  
Figure 1  
Figure 3  
6
7
The remote sample tube should be connected to the barbed  
inlet fitting on the bottom of the ATX612 (See Figure 3).  
4.1.1 ALKALINE BATTERY OPTION  
The ATX612 is available with an optional alkaline battery  
pack which will typically operate continuously for up to  
20 hours using 6 C-cell batteries.  
NOTE: When drawing a remote sample, allow 2 seconds  
per foot (0.3 meter) of tubing length in addition to  
the normal sensor response time before observing  
the instrument readings.  
WARNING: Replace alkaline battery cells only in a  
!
non-hazardous location. Use only Duracell, Energizer,  
Procell, Panasonic, Varta or Kodak C-cell alkaline batteries. Use  
of another battery type may present a risk of fire or explosion  
and will violate the intrinsic safety certification of the ATX612.  
The instrument is protected from drawing liquid and dust  
into the pump and sensors by an internal 1.2 micron dust  
filter/water stop.  
4.2 TURNING THE ATX612 ON AND OFF  
4.5 OPERATING MODES  
• Press and hold the ON/OFF/MODE switch. The display  
will read HOLD and the instrument sounds a short beep  
once a second.  
The ATX612 offers different operating modes to access  
various instrument features. To scroll through the  
operating modes, press and release the MODE switch. The  
operating modes will appear in the following order:  
HOLD  
• Continue holding the MODE switch for 5 beeps until the  
RELEASE screen appears. (Stop here if turning the  
instrument off.)  
O 0  
4.5.1 READING  
RELEASE  
21.0 0  
This is the normal operating mode. The current reading of  
all sensors is displayed along with the graphical battery  
charge indicator.  
• After the instrument is turned ON, the following startup  
screens will be displayed:  
ATX612  
VER 1.0  
SOFTWARE VERSION: The version of the operating  
software installed in the instrument is displayed.  
CO H2S  
02 LEL  
4.5.2 SENSOR CONFIGURATION  
This mode will display the type of sensor in the position in  
which it is installed in the instrument.  
SENSOR CONFIGURATION. The type of sensors  
installed in the instrument will be displayed.  
CO H2S  
02 LEL  
WARM-UP TIMER. The display will indicate the  
number of seconds remaining until the instrument begins  
normal operation.  
PPM EXP  
0
4.5.3 PPM HYDROCARBON  
This mode displays the level of total hydrocarbons with 50  
PPM resolution. The PPM reading may be rezeroed at  
anytime by pressing the enter (E) key. The display will  
return to the normal operating mode if the gas  
concentration exceeds the LEL alarm level set in the  
instrument.  
After the warm-up sequence has been completed, the  
ATX612 will enter the normal operating mode and will  
be continuously monitoring all calibrated sensors.  
5
4.3 DISPLAY BACKLIGHT  
4.5.4 ZERO  
ZERO  
This mode allows the user to zero the instrument and  
calibrate all installed sensors. Refer to Section 5,  
Calibrating the ATX612, for instruction on the use of the  
automatic zero and calibration functions.  
The display backlight is automatically switched on when  
the ATX612 is in an alarm condition. To manually activate  
the backlight, press and release the (E) key. The backlight  
will remain on for approximately 15 seconds.  
PRESS  
4.5.5 PEAK  
65P 8  
4.4 INTERNAL SAMPLING PUMP  
This mode will display the highest level of toxic and  
combustible gas and the lowest level of oxygen measured  
since the peak readings were last cleared.  
19.3K 12  
The ATX612 is equipped with a built-in pump for remote  
gas sampling. The sampling pump will draw a constant flow  
sample from up to 100 feet (30 meters) using 1/8 inch (3  
mm) diameter tubing.  
8
9
4.6.2 HIGH ALARM  
4.5.6 PEAK CLEAR  
PK CLR  
PRESS  
When a monitored gas concentration reaches the high  
alarm level setpoint, the instrument emits a continuous dual  
tone alarm. As with the low alarm condition, the red alarm  
light bar and backlight will flash simultaneously with the  
displayed gas value. If the hygiene/datalogging option is  
installed, the STEL alarm will mimic the high alarm  
indicator and the STEL display value in alarm will flash.  
This mode will clear all stored peak readings from the  
instrument. Press enter (E) to clear the peak readings. The  
display will return to the PEAK mode and indicate that the  
peak readings have been reset.  
If the hygiene/datalogging option is installed, the following  
operating modes may also be accessed. See Section 7,  
Hygiene/Datalogging Functions, for further instructions.  
NOTE: The ATX612 uses the continuous high alarm tone  
for both low (depletion) and high (enrichment)  
oxygen alarm conditions.  
4.5.7 DATE  
This screen allows the user to see the current date  
(month/day).  
DATE  
5/21  
4.6.3 OVER-RANGE INDICATION  
+OR 0  
21.0 0  
4.5.8 CAL DATE  
This mode allows the user to see the date the instrument  
was last calibrated.  
An over-range condition occurs when a sensor reading  
exceeds the upper limit of the instrument display range.  
Over-Range is indicated by +OR in the appropriate sensor  
display location. With the exception of combustible gas  
over-range, all over-range conditions will clear  
automatically when the gas concentrations have decreased  
to levels within the display range of the instrument.  
CALDATE  
5/13  
4.5.9 LOG TIME  
RT06:45  
LT01:15  
This mode allows the user to view the current real time  
(RT) and the length of time that data has been recorded in  
the current session (LT).  
4.6.4 COMBUSTIBLE GAS OVER-RANGE  
4.5.10 TWA (Time-Weighted Average)*  
This mode displays the current time-weighted average  
exposure values of the toxic sensors.  
When the ATX612 detects combustible gases in excess of  
100% of LEL (5% CH4 by volume), a high alarm  
condition is latched (locked on) and +OR is displayed in  
place of the combustible gas reading. Power is removed  
from the combustible gas sensor to prevent damage due to  
the high level of combustible gas.  
0 0  
TWA  
4.5.11 STEL (Short Term Exposure Limit)*  
This mode displays the short term average exposure values  
of the toxic sensors installed in the instrument.  
0 0  
STEL  
To clear the combustible gas over-range alarm:  
O 0  
• Exit the hazardous area immediately.  
• Press (E) key in clean air.  
4.5.12 HYGIENE RESET  
This mode allows the user to reset the hygiene session and  
the STEL and TWA exposure values.  
21.0 +OR  
HYGIENE  
PRESS  
NOTE: When the instrument is turned on, the combustible  
gas level must be less than 100% of LEL (5%  
CH4) to clear the combustible gas over-range  
condition.  
TWA and STEL  
*
4.6 ALARM INDICATORS  
4.6.1 LOW ALARM  
When a monitored gas concentration reaches the low level  
alarm setpoint, the instrument emits a short beep  
approximately every 1.2 seconds. The red alarm light bar  
and backlight will flash simultaneously along with the  
displayed gas value. If the hygiene/datalogging option is  
installed, the TWA alarm will mimic the low alarm  
indicator and the TWA display value in alarm will flash.  
readings do not  
apply to oxygen  
and combustible  
gas exposure.  
4.6.5 LOW BATTERY WARNING  
With 15-60 minutes of run time remaining, the ATX612  
will emit a short beep once every 60 seconds and the  
battery status indicator will be replaced with a flashing  
“B” to indicate the low battery condition.  
O 0  
21.0 0  
B
NOTE: The length of warning time will increase when  
there is no combustible gas sensor installed in the  
instrument.  
11  
10  
If an instrument fails to operate properly following any  
functional “bump” test, a full instrument calibration  
should be performed prior to use.  
4.6.6 BATTERY FAILURE  
BATTERY  
FAIL  
When the battery has insufficient charge to operate the  
instrument, “BATTERY FAIL” is displayed. The visual  
alarm will be activated and the instrument will emit a  
short beep once every second for approximately 30  
seconds after which the instrument will turn itself off.  
Recharge or replace the battery (See Section 8.2).  
Calibration is most accurate when the instrument has been  
in a stable temperature environment for at least one hour  
prior to calibrating.  
NOTE: Instrument zero and oxygen span calibration  
should be performed in clean air containing  
20.95% (21%) oxygen. If you are measuring a  
known combustible gas, use a known  
4.6.7 FAULT INDICATION  
The ATX612 will emit a short beep once a second if a  
newly installed sensor does not agree with the previous  
sensor type for that position. The corresponding display  
position will be blank. This fault indication also occurs  
when a sensor becomes disconnected or a combustible  
sensor fault is detected during normal operation. Installed  
sensor types are accepted and displayed only after a  
successful calibration has been completed.  
concentration of that gas for calibration. For  
general combustible gas measurement, Industrial  
Scientific Corporation recommends calibrating to  
pentane in the 15-50% LEL range. The measured  
LEL concentration of gases other than the  
calibration gas may not correspond on a one-to-  
one basis with the monitor reading. Always use  
teflon or teflon-lined tubing when calibrating.  
The sampling pump system is equipped with a low flow  
detection alarm. A low flow alarm condition will occur if  
the dust filter/water stop becomes clogged or the sample  
line becomes blocked in any way. The instrument will  
sound a continuous tone, the red alarm light bar will flash  
and the display will read PUMP FAULT. If this should  
occur, replace the dust filter/water stop immediately (See  
Section 9). The unit will not operate and a low flow alarm  
condition will remain if the dust filter/water stop is  
removed from the instrument. The PUMP FAULT alarm  
will be reset once the obstruction has been cleared from  
the sample line.  
The ATX612 utilizes a one-button calibration system.  
When using multi-gas cylinders, a full instrument  
calibration can be performed in a single step. Multi-gas  
cylinders are available for the most common instrument  
configurations.  
PUMP  
FAULT  
To calibrate the ATX612:  
• From the normal READING mode, press the MODE  
switch twice to access the ZERO operating mode.  
ZERO  
PRESS  
• Press the (E) key to start the instrument zeroing process.  
The instrument display will indicate ZEROING.  
• When zeroing is complete the instrument display will  
indicate O2 CAL and will show the current full span  
value of the oxygen sensor. The oxygen sensor will be  
calibrated to 21.0 in approximately 30 seconds.  
ZEROING  
CALIBRATING THE ATX612  
5.  
The ATX612 is a potential life saving device. Recognizing  
this fact, Industrial Scientific Corporation recommends  
that a functional (“bump”) test be performed on every  
instrument prior to each use. A functional test is defined as  
a brief exposure of the monitor to a known concentration  
of gas(es) for the purpose of verifying sensor and alarm  
operation. It is not intended to be a measure of the  
accuracy of the instrument.  
Instrument zeroing and oxygen calibration may be aborted  
at any time by pressing the MODE switch.  
21.0  
02 CAL  
NOTE: Zeroing the instrument in clean air is preferred,  
provided that there is no trace of toxic or  
combustible gas. If the air purity is uncertain, use  
a cylinder of zero grade air to zero the instrument  
and span the oxygen sensor.  
Industrial Scientific also recommends that a full  
instrument calibration be performed using a certified  
concentration(s) of calibration gas(es) monthly to ensure  
maximum accuracy.  
• At the completion of the oxygen sensor calibration, the  
instrument will emit a short beep and the display will  
indicate GO CAL. The message PRESS (E) to CAL will  
scroll across the bottom of the display. Press (E) to  
continue calibrating the remaining sensors. If you ignore  
this message the instrument will return to the normal  
operating mode in approximately eight seconds.  
13  
12  
• To continue full calibration, press (E) and the instrument  
will display the first sensor to be calibrated along with  
the calibration gas setting. The message APPLY CAL  
GAS will scroll across the bottom of the display.  
GO CAL  
PRESS  
CHANGING INSTRUMENT SETTINGS  
Instrument settings, including alarm values, calibration gas  
concentrations and security code, may only be accessed  
and changed during the instrument startup sequence.  
6.  
NOTE: If the gas concentration does not match the  
setting, press the MODE switch to abort  
calibration. See Section 6.1, SETSPAN to change  
the calibration gas settings.  
25 LEL  
APPLY  
The (+) and (-) hidden keys are used to set instrument  
alarm and calibration values. Refer to page 6, Figure 1 for  
the location of the hidden keys.  
NOTE: APPLY CAL GAS means connect the sample  
tubing to the appropriate calibration gas cylinder  
with either a ILPM or preferrably a demand flow  
regulator. Connect the tubing to the gas sample  
inlet of the ATX612. Turn on gas supply.  
To access the instrument menus:  
• Turn the ATX612 off and back on again.  
• When the display shows the warm up timer, press the  
plus (+) and minus (-) keys simultaneously.  
• Apply the calibration gas. The instrument will wait for  
five minutes to sense that calibration gas has been  
applied before aborting and failing calibration. When the  
sensor detects a gas concentration greater than 50% of  
the calibration gas value, the display will indicate the  
current full span value for that sensor. The message CAL  
IN PROGRESS will scroll across the bottom of the  
display.  
If the instrument security code has been set to a value  
other than “0”, the CODE screen will be displayed along  
with the scrolling prompt PRESS (+) OR (-) TO SET (E)  
TO ENTER. Use the (+) and (-) keys to input the correct  
security code value and press (E). When the correct code  
has been entered successfully, the instrument will  
immediately enter the settings mode.  
CODE 0  
PRESS  
• When calibration of the sensor has been successfully  
completed, the instrument will automatically step to the  
next sensor to be calibrated and the preceding step will  
be repeated.  
The settings mode consists of three functions:  
SETSPAN  
ALARMS  
CODE  
• When all sensors have been calibrated successfully the  
instrument will emit a short beep and the sensor  
configuration will be shown on the display.  
The scrolling prompt, PRESS (+) FOR NEXT (E) TO  
SELECT appears on each screen. Press the (+) to step  
through the list and (E) to select any of the functions.  
Pressing the MODE switch at any one of the functions  
will cause the instrument to return to the normal  
operating mode.  
• If calibration results in marginal sensor span values,  
sensor identifiers will flash on the display. Marginal  
calibration will occur if the sensor full span value is less  
than 70% of the applied gas concentration. A marginal  
sensor calibration may be an early warning sign that the  
sensor will soon need to be replaced.  
6.1 SETSPAN  
NOTE: If the sensor full span value is less than 50% of  
the calibration gas value, calibration will fail and  
the instrument will immediately return to the real  
time READING mode. When failed calibration or  
low sensitivity is indicated, verify that the  
The SETSPAN function allows the user to set the  
combustible sensor monitoring range to either LEL or CH4  
and to set the calibration gas values for the combustible  
and toxic sensors.  
SETSPAN  
PRESS  
calibration cylinder has not emptied or that the  
cylinder expiration date has not passed.  
• After displaying the sensor configuration, the  
instrument will automatically return to the real time  
READING mode.  
15  
14  
• Press (E) to enter the SETSPAN function. The display  
will show LEL along with the prompt PRESS (+) TO  
CHANGE.  
• Press (+) to step to the INSTANT function and set  
instantaneous alarm values. The display will indicate  
INSTANT along with the scrolling prompt PRESS (+)  
FOR NEXT (E) TO SELECT.  
LEL  
INSTANT  
PRESS  
PRESS  
• Press (+) to toggle between LEL and CH4 combustible  
sensor span ranges.  
• Press (E) to enter the instantaneous alarms function. The  
display will show the first alarm to be set along with the  
scrolling prompt PRESS (+) FOR NEXT (E) TO  
SELECT. The alarm type will be indicated on the display  
as either high (H) or low (L).  
10L LEL  
PRESS  
25 LEL  
PRESS  
Press MODE to enter the calibration gas values for all  
sensors. The display will show the first span value, eg.  
25 LEL, along with the prompt PRESS (+) FOR NEXT  
(E) TO SELECT.  
• Press (E) to select the desired alarm to be changed. The  
display will flash the current alarm value along with the  
prompt PRESS (+) OR (-) TO SET (E) TO SELECT.  
• Press (E) to select the value you wish to change. The  
display will flash the current gas value and will scroll the  
prompt PRESS (+) or (-) TO SET (E) TO ENTER.  
• Press the (+) and (-) keys to set the desired alarm value  
and (E) to enter the value into memory.  
• Press the (+) and (-) minus keys to set the desired  
calibration gas value and (E) to enter the value into  
memory. Once the value has been entered into memory,  
it will become the standard gas value used during  
instrument calibration.  
• Press MODE to return to the INSTANT function.  
• Press (+) to step to the TWA and STEL alarm functions.  
The TWA and STEL alarm values are set as  
previously described.  
• Press the MODE switch to return to the SETSPAN  
function.  
6.3 CODE  
6.2 ALARMS  
CODE  
The CODE function allows the user to select a security  
code to protect calibration and all instrument alarm  
settings. When the code is set to any value other than “0”,  
the user will be prompted to enter the proper code prior to  
entering the settings or calibration modes.  
The ALARMS function allows you to set the values for  
the HI and LOW alarms for each installed sensor. Default  
alarm settings for each gas are listed in Section 11. If the  
hygiene/datalogging option is installed, you will also be  
able to set the STEL and TWA alarm values.  
PRESS  
CODE 123  
PRESS  
• Press (+) to step from the ALARMS function to the  
CODE function.  
• Press (+) to step from the SETSPAN function to the  
ALARMS function.  
LATCH  
• Press (E) to enter the code function. The display will  
show the current code setting along with the scrolling  
prompt PRESS (+) OR (-) TO SET (E) TO ENTER.  
• Press (E) to enter the ALARMS function. The LATCH  
function will lock the alarm indicators on when a  
monitored gas concentration reaches the high alarm  
setpoint. The alarm will reset after the gas concentration  
has fallen below the alarm setpoint and the user has  
pressed the (E) key. The display will indicate LATCH  
along with the scrolling prompt PRESS (+) FOR NEXT  
(E) to SELECT.  
• Press the (+) and (-) keys to set the code to any value  
between 0 and 999, and (E) to enter the value  
into memory.  
ALARMS  
PRESS  
• Press MODE to return to the CODE function.  
LATCH  
PRESS  
• Press (E) to select the LATCH function. The display will  
indicate LATCH along with the prompt PRESS (+) FOR  
NEXT (E) TO SELECT.  
HYGIENE/DATALOGGING FUNCTIONS  
7.  
OFF  
7.1 DEFINITION OF TERMS  
• Press (E) to set the ATX612 high alarm latch as ON or  
OFF. Press MODE to return to the LATCH screen.  
PRESS  
7.1.1 DATA LOG  
The record of measured gas concentrations, including time  
and date, stored in the instrument’s electronic memory.  
17  
16  
The datalogging section of the instrument is always  
powered and a battery backup circuit protects it from loss  
of data for up to 40 minutes during battery changes.  
7.1.2 PERIOD  
The logging time that begins when the instrument is  
turned on and initiates normal operation and lasts until the  
instrument is turned off.  
NOTE: The instrument must be stored on a battery  
charger when not in use to prevent loss of data  
due to battery discharge.  
7.1.3 LOGGING SESSION  
One or more periods of normal instrument operation  
between hygiene function resets.  
7.3 RESETTING THE HYGIENE FUNCTIONS  
RT06:45  
LT00:00  
7.1.4 REAL TIME CLOCK  
The internal clock that maintains the current time.  
NOTE: If you are using the datalogging feature, be sure  
the correct date and time are programmed by  
checking/setting the Real Time Clock and  
Calendar using the optional ATX  
7.1.5 LOG TIME CLOCK  
The running clock that monitors the length of time logged  
during a session.  
Hygiene/Datalogging Software.  
RTOR:OR  
LT00:00  
• Press MODE repeatedly to step to the HYGIENE screen.  
• Press (E) to reset the hygiene function and begin a new  
datalogging session.  
7.1.6 CALENDAR  
A part of the real time clock that maintains the  
current date.  
The instrument display will return to the LOG TIME  
mode and the display will indicate that the log time (LT)  
will be reset to 00:00. The TWA and STEL values for all  
toxic sensors will also be reset to zero.  
RTOR:OR  
LT0R:0R  
7.1.7 TWA (TIME-WEIGHTED AVERAGE)  
The accumulated gas exposure averaged over a  
predetermined time, typically eight hours.  
If there is insufficient memory to log approximately 12  
hours of data when the hygiene function is reset, the real  
time clock value will be displayed as RTOR:OR.  
7.1.8 STEL (SHORT TERM EXPOSURE LIMIT)  
The accumulated gas exposure value averaged for the  
proceeding fifteen minutes.  
When the memory is full, both the real time and log time  
will be displayed as OR:OR. At this time, the data may be  
cleared by performing a hygiene reset as described above.  
All currently stored data will be overwritten. The stored  
data may be down-loaded using the ATX  
7.2 PRINCIPLES OF OPERATION  
hygiene/datalogging software.  
If the ATX612 is equipped with the hygiene/datalogging  
option, all sensor readings are sent to the hygiene module.  
Once every minute the readings are averaged, saved to the  
memory and the TWA and STEL values are calculated for  
the toxic sensors. The TWA and STEL values are then  
tested for possible alarm conditions.  
7.4 DOWNLOADING THE ATX612  
To connect the ATX612 for downloading data to the PC:  
• Start the datalog software on the PC.  
The default time base for calculating TWA values is eight  
hours. However, the time base may be changed to any  
value in the range from one to 40 hours using the  
optional ATX Hygiene/Datalogging Software and a  
personal computer.  
• Connect the interface cable to the infrared data port on  
the bottom of the ATX612.  
• Select CONNECT from the menu on the datalog  
software.  
The instrument memory provides storage capacity for  
approximately 110 hours of logged data in an instrument  
with four sensors installed.  
• Turn on the instrument when prompted.  
• The ATX612 will show CONNECT and the instrument  
will begin communicating with the PC.  
18  
19  
• Remove the battery pack from the instrument as  
described in Section 8.2.  
MAINTENANCE  
8.  
• Remove the two screws which hold the battery module  
in place as shown in Figure 4.  
8.1 CLEANING  
• Lift the Nicad battery module from the battery pack.  
• Place the new Nicad module in the battery pack.  
Wipe the outside of the instrument with a soft, clean cloth.  
Never use solvents or cleaning solutions of any type.  
• Replace the two screws which hold the Nicad module  
in place.  
8.2 CHANGING THE BATTERY PACK  
To change the ATX612 battery pack:  
8.2.2 REPLACING ALKALINE BATTERY CELLS  
The alkaline battery pack holds 6 C-cell batteries. To  
replace the alkaline battery cells:  
• Hold the instrument with battery pack facing up.  
• Using the maintenance tool provided with the  
instrument, turn counter-clockwise and loosen the two  
hex screws in the battery pack.  
• Remove the battery pack from the instrument as  
described in Section 8.2.  
• Remove the battery pack. (See Section 8.2.1 for  
instructions of replacing the Nicad battery module)  
• Remove the alkaline cells from the battery pack.  
• Insert the new cells making sure to observe proper  
polarity.  
• Place the battery pack on the instrument.  
• Turn the hex screws clockwise until the screws are tight  
and reach the stops. DO NOT OVER TIGHTEN.  
NOTE: Proper polarity of the alkaline battery cells is  
identified by the molded “+” and “-” symbols in  
the bottom of the battery pack. In addition the  
positive (+) battery contact is identified by the red  
polarizing tab.  
8.2.1 REPLACING THE NICAD BATTERY MODULE  
The Nicad cells within the battery pack may be replaced  
when necessary by installing a new Nicad battery module.  
To replace the Nicad battery module:  
Battery Pack  
Hex Screws  
8.3 OPENING THE INSTRUMENT FOR SERVICE  
To open the instrument for service:  
Nicad Battery  
Module  
• Remove the battery pack as described in Section 8.2.  
• Remove the four screws from the bottom of the  
instrument chassis.  
• Gently lift the case top from the chassis.  
Battery Pack  
8.4 INSTALLING OR CHANGING SENSORS  
To change sensors in the ATX612:  
Figure 4  
• Open the instrument as described in Section 8.3.  
• Remove the three screws which hold the sensor manifold  
in place.  
• Gently lift the sensor manifold away from the chassis as  
shown in Figure 5.  
NOTE: It is not necessary to disconnect the sample tubing  
from the manifold to replace the sensors.  
Figure 5  
20  
21  
WARNING: When removing a sensor from  
service, the appropriate sensor plug  
must be installed to ensure proper  
instrument operation. Toxic/O2  
Sensor Plug P/N 1704-6947  
Combustible Sensor Plug  
!
REPLACEMENT PARTS  
The following items numbers refer to the exploded view  
drawing on pages 24 and 25.  
9.  
Shorting Wire  
P/N 1706-2647  
ITEM PART NUMBER DESCRIPTION (QTY)  
8.4.1 TOXIC/OXYGEN SENSOR REMOVAL/  
REPLACEMENT  
• To remove a toxic or oxygen sensor, grasp the sensor  
and lift it straight up. Use care to avoid bending the  
sensor pins.  
1
2
3
4
5
6
or  
7
8
9
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
1705-8868  
1705-6755  
1705-9247  
1705-9031  
1706-3447  
1705-9494  
1705-9312  
1706-0716  
1706-2498  
1705-8157  
1705-7118  
1705-8660  
1705-8140  
1706-0674  
1702-8374  
1705-0295  
1706-1284  
1705-8306  
1706-0500  
1705-8652  
Main PC Board (1)  
Display PC Board (1)  
Interface PC Board (1)  
Chassis (1)  
Pump Assembly (1)  
Nicad Battery Pack  
Alkaline Battery Pack  
Case Gasket (1)  
Filter Housing (1)  
Dust Filter/Water Stop (1.2 Micron) (1)  
Speaker (1)  
Speaker Gasket (1)  
Speaker Water Barrier (1)  
Sensor Manifold (1)  
External Alarm Jack (1)  
RFI Screen (1)  
WARNING: When removing a toxic sensor for  
storage, connect a shorting wire to  
the two pins as shown.  
!
• New toxic sensors are shipped with a shorting wire  
attached. Remove the shorting wire from the new  
sensor.  
• Immediately install the sensor in the instrument. Never  
apply pressure to the area inside of the black O-Ring seal  
at the top of the sensor.  
8.4.2 COMBUSTIBLE SENSOR REMOVAL/  
REPLACEMENT  
• To remove the combustible sensor, grasp the sensor and  
lift it straight up.  
Case Top (1)  
Key Pad (1)  
Alarm Lens (1)  
Alarm Lens Gasket (1)  
• Press the new sensor firmly into the sockets on the  
PC board.  
8.5 CHANGING THE INTERNAL FILTER  
If the internal dust filter/water stop becomes blocked, a  
PUMP FAULT alarm will result. The filter must be  
replaced immediately before continuing operation. To  
remove and replace the internal dust filter/water stop from  
the instrument:  
• Unscrew and remove the knurled sample inlet fitting from  
the instrument as shown in Figure 6.  
• Grasp the dust filter/water stop from the instrument and  
pull straight out to remove.  
• Replace the dust filter/water stop making sure that the  
larger diameter opening of the filter is facing inward.  
• Replace the knurled sample inlet fitting.  
NOTE: The ATX612 will remain in a PUMP FAULT  
condition if operation is attempted with the dust  
filter/water stop removed.  
23  
22  
Figure 6  
25  
24  
SPECIFICATIONS  
10.  
DEFAULT ALARM SETTINGS  
11.  
LEL  
CH4  
CO  
H2S  
SO2  
NO2  
Cl2  
CASE:  
Type 304 Stainless Steel  
GAS  
LOW ALARM  
HIGH ALARM  
O2  
19.5%  
23.5%  
DIMENSIONS:  
8.2”L x 3.7”W x 3.2”H  
(208 X 94 X 81 mm)  
10%  
20%  
1.0%  
1.5%  
WEIGHT:  
SENSORS:  
3.4 lbs (1.5 kg)  
35 PPM  
10 PPM  
2.0 PM  
3.0 PPM  
0.5 PPM  
0.3 PPM  
70 PPM  
20 PPM  
4.0 PPM  
6.0 PPM  
1.0 PPM  
1.0 PPM  
Combustible Gases and Methane-  
Catalytic  
Oxygen and Toxic Gases-  
Electrochemical  
ClO2  
MEASURING RANGE:  
LEL (Combustible Gases)  
0 to 100% LEL in 1% increments  
NOTE: Factory alarm settings may not coincide with  
local regulations. Consult all appropriate local  
regulations for appropriate alarm settings in  
your region.  
CH4 (Methane)  
0 to 5% of volume in 0.1% increments  
O2 (Oxygen)  
0 to 30% of volume in 0.1% increments  
ATX612 OPTIONS & ORDERING INFORMATION  
12.  
CO (Carbon Monoxide)  
0 to 999 PPM (parts per million) in 1 PPM increments  
PART NUMBER  
DESCRIPTION (QTY)  
1705-0788-PPM  
1705-0129  
1704-1898  
1704-1880  
1704-1914  
1704-4204  
1704-1922  
1704-1906  
1810-1386  
1810-1428  
1705-9494  
1705-9312  
1810-3259  
1810-0628  
1810-2921  
1810-1154  
1810-2146  
1810-2187  
1810-1576  
1810-2165  
1810-1584  
1810-2222  
1810-1758  
1810-2219  
1810-2509  
Combustible Sensor  
Oxygen Sensor  
Hydrogen Sulfide Sensor  
Carbon Monoxide Sensor  
Chlorine sensor  
CLO2 sensor  
Nitrogen Dioxide Sensor  
Sulfur Dioxide Sensor  
Stainless Steel Extendible Probe - 6ft.  
Polycarbonate Probe  
Rechargeable Nicad Battery Pack  
Replaceable Alkaline Battery Pack (6 C-cell)  
Leather Carrying Case for ATX612  
Shoulder Strap  
Carrying Handle for ATX612  
External Audible/Visual Alarm  
External Vibrating Alarm  
Cylinder Cal. Gas, H2S, CO, Pentane and Oxygen  
Cylinder, Cal. Gas, Carbon Monoxide, Pentane and Oxygen  
Cylinder, Cal. Gas, Carbon Monoxide, Methane and Oxygen  
Cylinder, Cal. Gas, Zero Air  
H2S (Hydrogen Sulfide)  
0 to 999 PPM (parts per million) in 1 PPM increments  
SO2 (Sulfur Dioxide)  
0 to 99.9 PPM (parts per million) in 0.1 PPM increments  
NO2 (Nitrogen Dioxide)  
0 to 99.9 PPM (parts per million) in 0.1 PPM increments  
C12 (Chlorine)  
0 to 99.9 PPM (parts per million) in 0.1 PPM increments  
C1O2 (Chlorine Dioxide)  
0 to 99.9 PPM (parts per million) in 0.1 PPM increments  
POWER SOURCE: Rechargeable, replaceable nickel-cadmium battery  
pack, or replaceable cell alkaline battery pack  
BATTERY LIFE: With Nicad Battery Pack - 16 hours typical  
With Alkaline Battery Pack - 20 hours typical  
READOUT:  
Alpha-Numeric Liquid Crystal Display  
Cylinder, Cal. Gas, 5 PPM Sulfur Dioxide  
Cylinder, Cal. Gas, 10 PPM Chlorine  
Cylinder, Cal. Gas, 5 PPM Nitrogen Dioxide  
Demand Flow Regulator with Pressure Gauge  
TEMPERATURE RANGE:  
With H2S Sensor  
-
20ºC to 50ºC (-4ºF to 122ºF  
)
-40ºC to 50ºC (-40 F to 122 F)  
º
º
HUMIDITY RANGE:  
0% to 99% RH (Non-condensing)  
STORAGE TEMPERATURE: 0ºC to 20ºC (32ºF to 68ºF)  
26  
27  
13.  
WARRANTY  
It shall be an express condition to Industrial Scientific’s  
warranty that all products be carefully inspected for  
damage by Buyer upon receipt, be properly calibrated for  
Buyer’s particular use, and be used, repaired, and  
maintained in strict accordance with the instructions set  
forth in Industrial Scientific’s product literature. Repair or  
maintenance by non-qualified personnel will invalidate the  
warranty, as will the use of non-approved consumables or  
spare parts. As with any other sophisticated product, it is  
essential and a condition of Industrial Scientific’s warranty  
that all personnel using the products be fully acquainted  
with their use, capabilities and limitations as set forth in  
the applicable product literature.  
Industrial Scientific portable gas monitoring instruments  
are warranted to be free from defects in material and  
workmanship for as long as the instrument is in service.  
The above warranty does not include sensors, battery  
packs, internal pumps or filters, all of which are warranted  
to be free from defects in material and workmanship for  
eighteen months from the date of shipment, or one year  
from the date of first use, whichever occurs first, except  
where otherwise stated in writing in Industrial Scientific  
literature accompanying the product.  
All other Industrial Scientific products are warranted to be  
free from defects in material and workmanship for a  
period of eighteen (18) months from the date of shipment,  
or one (1) year from the date of first use, whichever  
occurs first, except where otherwise stated in writing in  
Industrial Scientific literature accompanying the product.  
Buyer acknowledges that it alone has determined the  
intended purpose and suitability of the goods purchased. It  
is expressly agreed by the parties that any technical or  
other advice given by Industrial Scientific with respect to  
the use of the goods or services is given without charge  
and at Buyer’s risk; therefore, Industrial Scientific  
assumes no obligations or liability for the advice given or  
results obtained.  
LIMITATION OF LIABILITY  
INDUSTRIAL SCIENTIFIC MAKES NO OTHER  
WARRANTIES, EITHER EXPRESSED OR IMPLIED,  
INCLUDING BUT NOT LIMITED TO THE  
WARRANTIES OF MERCHANTABILITY OR FITNESS  
FOR PARTICULAR PURPOSE.  
SHOULD THE PRODUCT FAIL TO CONFORM TO  
THE ABOVE WARRANTY, BUYER’S ONLY REMEDY  
AND INDUSTRIAL SCIENTIFIC’S ONLY  
OBLIGATION SHALL BE, AT INDUSTRIAL  
SCIENTIFIC’S SOLE OPTION, REPLACEMENT OR  
REPAIR OF SUCH NON-CONFORMING GOODS OR  
REFUND OF THE ORIGINAL PURCHASE PRICE OF  
THE NON-CONFORMING GOODS. IN NO EVENT  
WILL INDUSTRIAL SCIENTIFIC BE LIABLE FOR  
ANY OTHER SPECIAL, INCIDENTAL OR  
CONSEQUENTIAL DAMAGES, INCLUDING LOSS  
OF PROFIT OR LOSS OF USE, ARISING OUT OF THE  
SALE, MANUFACTURE OR USE OF ANY PRODUCTS  
SOLD HEREUNDER WHETHER SUCH CLAIM IS  
PLEADED IN CONTRACT OR IN TORT, INCLUDING  
STRICT LIABILITY IN TORT.  
28  
29  

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