Manning Systems AirScan iR comm Refrigerant Sensor Instruction and Installation Manual
Below you will find brief information for Refrigerant Sensor AirScan iR comm. The AirScan iR comm is a refrigerant sensor for commercial applications. It utilizes infrared technology to detect refrigerants such as R-123, R-134a, R-404a, R-507, and R-22. The sensor features a linear 4/20 mA output, a range of 0-3,000 ppm, and a response time of T in 10 seconds with full-scale target calibration gas at .75 liters/min flow rate. Key features include SensorCheck technology for self-monitoring and dual channel functionality, diffusion sampling with no moving parts, and environmental compensation for temperature and humidity fluctuations.
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Instruction and
Installation Manual
TM
AirScan
Refrigerant Sensor for
Commercial Applications
i
R
MOUNT ENCLOSURE THIS END UP. DO NOT BLOCK PERFORATED VENT HOLES.
AirScan
405 Barclay Boulevard
Lincolnshire, Illinois 60069
Tel: +1 847 955 8200
Toll free: +1 800 538 0363
[email protected] www.honeywellanalytics.com www.manningsytems.com
18908 AirScan-iR-comm 01/2014 REVC
Fax: +1 847 955 8208
Manning AirScan-iR Refrigerant Sensor
18908 AirScan-iR-comm 01/2006 REVA Copyright © 2006 Manning Systems, Inc. All Rights Reserved.
1
Contents
Serial number:
Section Title
1 Sensor Description System Specifications and Sensor Specifications
2 Installation A Locating the Sensor
Figure 1: Mounting Dimensions for the AirScan TM iR
3 Operation
Figure 2: Wiring Diagram for AirScan
TM iR
A Start-up Procedure
Figure 3: Required LED Status at Start-up
B Pushbutton Operation, LED Indicators, Adjustment Pots and Test Points
Figure 4: Board Component Layout
Figure 5: LED Layout
LED Indicators and Blink Sequence
Figure 6: LED Blink Sequence
Figure 7: LED Indicator Summary
Normal Run Modes
4/20 mA Loop Test Mode
Calibration Mode
Fault Indicator Error Sequences
C Modes of Operation
Normal Run Modes
4/20 mA Loop Modes
Calibration / Programming Modes
Calibration
Figure 8: Board Component Layout
4/20 mA Output Calibration
Zero Calibration
Figure 9: Board Component Layout
Simple Zero Test
4/20 mA Output Loop Integrity Check
Electrical
Figure 10: Troubleshooting the AirScan TM iR
Sensor On-Board Diagnostic System
Error on 4/20 mA Output
Sensor Output at 0 mA
Sensor Output at .5 mA
Gas Concentration Indicated with No Refrigerant Present
IR Source Failure
6 Limited Warranty
Page
10
7
7
24
Manning AirScan-iR Refrigerant Sensor
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2
Introduction
This manual has been prepared to help in the use and installation of the Manning Systems
AirScan
TM
iR (Infrared Refrigerants) Sensor. This manual will convey the operating principles of the sensor, ensure proper installation, and demonstrate start-up and routine maintenance procedures.
This manual must be carefully followed by all individuals who have or will have the responsibility for using or servicing the AirScan
TM
iR Sensor.
Warranties made by
Manning Systems, Inc. with respect to this equipment will be voided if the equipment is not used and serviced in accordance with the instructions in this manual. If in doubt about a procedure, please contact Manning Systems, Inc. before proceeding.
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1
Sensor Description
Gas detection by the infrared method is based on the principle that most gases absorb infrared energy at a characteristic frequency. In this instrument, a broad band infrared source emits energy which is then bandpass filtered to produce a narrow range of frequencies characteristic of the refrigerants’ (CFC/HCFC/HFC) absorption spectra. Any refrigerant in the gas sample cell selectively absorbs energy reaching the detector. This reduction in energy is detected, amplified and sent to the signal processing portion of the system.
The Manning Systems AirScan TM iR Sensor line is a threewire, 4/20 mA sensor for two bands of refrigerants available in a range of 0–3,000 ppm, but can be adjusted for lower ranges, if required. The low-band or R-404a infrared sensor reacts to R-123, R-134a, R-404a and R-507.
The high-band or R-22 AirScan
TM iR sensor reacts to R-22.
Its solid, high-mass metal bench provides structural and thermal stability, greater immunity to vibration, as well as superior EMI/RFI shielding of the detector and source.
Internal compensation for environmental changes allows the sensor to automatically adapt to fluctuating temperature and humidity conditions. The unit exhibits extremely high reliability with no moving parts.
Every two seconds SensorCheck
TM the AirScan TM
technology monitors iR source and ensures that the dual channels are functioning properly. A notification signal will be transmitted if any of several performance parameters is not met.
Monitoring equipment must be configured to indicate a fault if the signal is less than 1.5 mA. All signals over
20 mA must be considered a high gas concentration.
Manning Systems infrared sensors are normally longlived (5 years plus), unless physically damaged or wetted with water or other liquid.
System Specifications
Electrical Power:
24 Volts DC regulated, 1.0 amp.
Output:
Linear 4/20 mA output into a load resistor of
500 ohms maximum
Cable Length to Sensor:
1,000 feet maximum
Cable Recommendation:
Three conductor, stranded, shielded cable with drain wire, all enclosed in a vinyl jacket. For cable runs up to 200 feet use, #18 AWG
(Belden #8770 or equivalent). For cable runs up to 1,000 feet, use #16 AWG (Belden #8618 or equivalent).
Unit Enclosure:
NEMA 4, gasketed, molded fiberglass reinforced polyester. Non-painted, non-rusting construction appropriate for food areas. UL 508 listed,
CSA certified for use with industrial control equipment.
NOTE:
The standard AirScan classified areas only.
TM iR is for use in non-
Sensor Specifications
Type:
CFC/HCFC/HFC selective infrared gas sensor/ transmitter AirScan TM iR
Method of Detection:
Dual channel infrared energy absorption (N.D.I.R. Non-dispersive Infrared)
Gases Monitored:
Low-Band (R-404a, R-507, R-134a, and R-123), High-Band (R-22)
Range Available:
0–3,000 ppm (can be rescaled to
0–1,000 ppm, or 0–500 ppm if required)
SensorCheck
TM
Features:
Dual channel functionality test, source strength evaluation, incoming voltage monitor,
IR source integrity check, operating temperature monitor,
“zero” down drift monitor, and internal circuitry check.
Accuracy:
± 3% of full scale
Repeatability:
± 1% of full scale
Cross Sensitivity:
Not affected by moisture, food odors, floor cleaners, temperature changes, etc.
Operating Humidity:
0–100% RH (condensing)
Operating Temperatures:
–20° F to +140° F
Storage Temperature:
–20° F to +140° F
Gas Sampling:
Diffusion method with no moving parts
Sampling Frequency:
Real time continuous monitoring of all points
Response Time:
T
90
in 10 seconds with full-scale target calibration gas @ .75 liters/min. flow rate
Weight:
4.4 lbs.
Dimensions:
9.59" high x 7.71" wide x 4.52" deep
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Installation
A
Locating the Sensor
Because each sensor can only “report” what it is seeing at the moment,
it is very important that the sensor be located where leaks are most likely to occur.
CFC/ HCFC/HFC vapor is heavier than ambient air, so in a room with no air movement it will tend to settle. For quickest detection, mount the sensor about one to two feet from the floor, close to the potential leak source.
If the primary application is the fastest possible leak detection, mount the sensor near the potential leak sources. In doing this, be aware that the indicated concentration may not be representative of personnel exposure and easy access for the required calibration and maintenance could be compromised.
General Mounting Considerations:
• Must be easily accessible for calibration and maintenance.
•
Always
mount the sensor vertically.
• Mount the sensor close to the potential leak source for fastest possible leak detection.
• If personnel protection is the primary application, mount in the “breathing zone.”
• Protect sensor from water, excessive humidity, and wash-down.
• Take air movement and ventilation patterns into account.
Figure 1: Mounting Dimensions for the AirScan
TM iR Sensor
MOUNT ENCLOSURE THIS END UP. DO NOT BLOCK PERFORATED VENT HOLES.
AirScan
9.59”
3.68”
• To prevent electrical interference, keep sensor and wire runs away from mercury vapor lights, variable speed drives, and radio repeaters.
• Protect sensor from physical damage (fork lifts, etc.).
• Do not mount the sensor over a door in a refrigerated area.
• For highly critical locations more than one sensor should be installed in each room.
Very Important:
• Sensor be mounted vertically
•
Never
mount sensor flat on a ceiling
• Enter
only
through existing hole in bottom of enclosure
•
Always
make a drip loop in the conduit
•
Never
mount sensor on a vibrating surface.
Mount sensor enclosures through the flange holes as shown in Figure 1, and
always mount vertically.
Penthouses:
Multi-Coil (defrost one coil at a time) –
In this case the best location is usually in the center of the penthouse four or five feet above the grate.
Single Coil (or when all coils defrost at the same time) –
In this case high moisture conditions can occur and the sensor should be mounted one foot above the grate.
Engine Rooms:
The AirScan TM iR sensor should be mounted in a cool part of the room, if possible. Keep the sensor away from hot air exhausting from electric motors or other machinery.
9.19”
1”
7.71”
4.52”
5.01”
FRONT VIEW
Manning AirScan-iR Refrigerant Sensor
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SIDE VIEW TOP VIEW
5
2
Installation
continued
Ceiling Hung Evaporators:
When mounting AirScan
TM iR sensors near evaporators, mount the sensor no higher than two feet below the top of the evaporator coil.
Do not
mount in high air flow (1,200 feet/minute maximum).
Never
mount the sensor on evaporators as vibration can damage the sensor.
Other Locations:
When mounting AirScan
TM iR sensors in locations such as roof top air units, ductwork, attic spaces, makeup air intakes, etc., contact Manning Systems for application assistance and recommendations.
B
Wiring
Electrical wiring must comply with all applicable codes.
Plant equipment that may be involved and operating conditions should be discussed with local operating personnel to determine if any special needs should be considered.
Nearly all start-up problems are due to improper wiring or monitor configuration. Please follow these guidelines carefully.
Always use three conductor, insulated, stranded, shielded copper cable. Use
only
three conductor cable,
not
two cables of two conductor wire (see Figure 2).
If the AirScan
TM iR is to be used with the AirAlert
TM
96d, please call Manning Systems for specific wiring instructions.
Do not pull sensor wiring with AC power cables.
This will cause electrical interference. Be sure there are no breaks or splices in sensor wiring runs. If cable runs cannot be made without a splice, all connections must be soldered.
Soldering should be done using a rosin flux to tie the connecting ends of sensor wires to ensure a positive and long-lasting contact.
Figure 2: Wiring Diagram for the AirScan
TM
iR Sensor
White connects to signal input of monitoring equipment
Red connects to 24 VDC power supply positive side
Output (white)
+24 VDC (red)
Black connects to 24 VDC ground side
Bare wire wrap connects to case ground at monitoring equipment (earth ground)
DC ground (black)
Shield (bare)
Ground the shield at the main control panel. Connect the shield wire in the sensor terminal block labeled
shield. Tape all exposed shield wire at the sensor to insulate it from the enclosure.
All penetrations into a refrigerated room should be sealed to prevent condensate from forming in the conduit and dripping into the sensor enclosure.
Make drip loops for cables going into sensor housings
(see Figure 1). Follow the special mounting instructions on the enclosure (…This End Up).
Electrical Power:
24 VDC regulated, 1.0 amp.
Output:
Circuit board mounted sensor provides a linear
4/20 mA output. Monitoring equipment may have a maximum input impedance of 500 ohms.
Contact Manning Systems for specific wiring instructions when using AirScan
TM iR sensors with an
AirAlert TM 96d readout unit.
Cable Recommendation:
Use #18/3 (Belden #8770) for cable runs up to 200 feet. Use #16/3 (Belden
#8618) for cable runs up to 1,000 feet. Use only the existing punched holes for connections to the sensor.
Monitoring:
The AirScan
TM iR Refrigerant Sensor may be monitored by any Manning Systems Readout/Alarm unit or other appropriately configured system. Monitoring equipment must be configured to indicate a fault if the signal is below 1.5 mA. All signals above 20 mA must be considered a high gas concentration. A failed sensor will output a 0.5 mA signal.
JP1
SIG
+24
GND
SHLD
TEST +
TEST -
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3
Operation
The AirScan
TM i
R has several modes of operation, including two normal run modes, two 4/20 mA loop check modes and five calibration modes. These will be explained in Operation, Section C, Modes of Operation.
Modes are entered by properly activating pushbuttons located on the circuit board, shown in Figure 4.
Sensor operation status is indicated by the blink pattern of seven LEDs located in a vertical row on the right side of the sensor circuit board (see Figure 4).
LED status is differentiated by color and duration/ pattern of blink(s). LED Indicators and Blink
Sequences are shown in Figure 6, followed by an explanation of blink patterns.
A
Start-Up Procedure
IMPORTANT:
The AirScan
TM iR sensor is factory calibrated and should require minimal adjustments after installation.
CARB Compliance:
To ensure continued compliance with CARB performance guidelines, calibrate the unit in the environment in which it will be used. Frequency of calibration can improve accuracy; Honeywell
Analytics recommends calibration every 6 months.
Environmental factors such as temperature, humidity, and pressure can affect accuracy. Consider these factors when establishing a maintenance program .
Before applying power, make a final check of all wiring for continuity, shorts, grounds, etc. It is usually best to disconnect external alarms and other equipment from the sensor until the initial start-up procedures are completed.
Allow the sensor to operate for 12 hours with the enclosure sealed prior to testing the sensors. This will give the sensor time to reach thermal equilibrium to the external and internal temperatures while in operation.
Because sensors are normally located at a distance from the main unit, the test time required and accuracy of the response checks will be improved if two people perform the start-up procedures and use radio contact.
Check the power supply voltage to the sensor with a digital volt meter set to VDC. Place the black lead on sensor terminal GND and the red lead on +24 (see
Figure 4, Note 1). Voltage should be between 21 and 28
VDC. If voltage is outside this range, check power supply and wiring.
After power-up, ensure the LEDs below are operational as follows (see Figure 3):
Start-Up Test:
1)
One person exposes each sensor to a small amount of the gas that is being monitored.
2)
The second person stays at the control unit to determine that each sensor, when exposed to the gas fumes, is connected to the proper input and responds, causing appropriate alarm functions.
• Green “Power” LED continuous ON
• Both Fault LED’s are OFF
• Green “source” LED is blinking once every
2 seconds
NOTE:
For cold/humid adverse environmental conditions the “ATMOS” LED may be turning on and off periodic- ally. In addition, the “system” LED may be blinking or continuous ON, also described in later sections.
Figure 3: Required LED Status at Start-up
LED
POWER
G
SYSTEM
Y
CALIBRATE Y
WITH OUTPUT
FILTERING
OFF
FAULT R OFF
WITHOUT OUTPUT
FILTERING
OFF
OFF
OFF OFF mA FAULT R
SOURCE G
ATMOS G ON PERIODICALLY ON PERIODICALLY
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3
Operation
continued
B
Pushbutton
LED Indicators,
Adjustment Pots and
Test Points
The AirScan TM iR has two internal pushbuttons, and two adjustment pots that are utilized for navigation of test functions, calibrations, and operating modes. In addition, a pair of test points is also provided that assist in the connection to standard meter leads for use in the upcoming calibration and diagnostic procedures (see
Figure 4).
Figure 4: Board Component Layout
Zero Adjust
Span Adjust
ICSP Programming Port
Pushbutton S1
Pushbutton S2
Serial Port
Rx LED Tx LED
JP3 JP2
Note 1: Checking voltage to sensor at +24 and GND
24
VDC
Black
-
Red
+
Note 2: Reading signal at TEST+ and TEST-
40-200 mVDC
ZERO
S1
SPAN
S2
JP1
SIG
+24
GND
SHLD
TEST +
TEST -
Draw
Chamber
POWER
SYSTEM
CALIBRATE
FAULT mA FAULT
IR SOURCE
ATMOS
ACTIVE
•
“Zero” adjustment pot – adjusts output calibration of the 4 mA nominal resting point
•
“Span” adjustment pot – adjusts the 20 mA concentration level or unit span/sensitivity.
•
Pushbutton S1 – used to initiate the auto-zero function, program the 4 mA output calibration, and initiate the 4/20 mA loop test.
•
Pushbutton S2 – used to program the span setting.
•
Test(+) and Test(–) for connection to a DC Volt meter (see Figure 4, Note 2).
IMPORTANT:
The pushbutton(s) must be pressed the correct number of times and at the correct rate.
• When a multi-press sequence must be performed, the button must be pressed rapidly and evenly, lifting one’s finger completely from the actuator for each consecutive press.
• For press and hold activations, one’s finger must always be applying a down pressure without disruption for the specified time in order to activate the desired mode.
• See complete details of each operation in other parts of the manual.
The AirScan
TM iR also has a group of LED’s (see Figure 5) that blink in specific sequences (see Figure 6 on next page) to indicate sensor operation and programming modes. A summary of sensor operation and programming modes with corresponding LED blink
sequences is shown in Figure 7 on page 10.
Figure 5: LED Layout
Draw
Chamber
Black
-
Red
+
Tubing to calibration point
POWER
SYSTEM
CALIBRATE
FAULT mA FAULT
IR SOURCE
ATMOS
ACTIVE
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Operation
continued
LED Indicators and Blink Sequence
Figure 6: LED Blink Sequence
SEQUENCE
SOURCE BLINK
SLOW BLINK
MEDIUM DOUBLE BLINK
FAST BLINK
CONTINUOUS ON
1 sec.
2 sec. 3 sec.
Green Power LED
• Continuous ON when power is applied
Yellow System LED
• Continuous ON during normal filtered output run mode – “dead band” from 4 to 4.6 mA
• Slow blink during normal non-filtered output run mode
• Fast blink indicating unit lost calibration data
• OFF during 4/20 mA loop check
Yellow Calibrate LED
• Continuous momentary ON for auto-zero mode activation
• Slow blink for 4 mA output calibration mode
• Medium double blink indicates 4/20 mA loop check .5 mA (low)
• Fast blink for “span” calibration mode and
4/20 mA loop check 22 mA (high)
Red Fault LED (all scenarios produce a .5 mA output)
• Continuous ON indicates a failed source, low signal, or circuit failure
• Slow blink indicates the power supply DC 24V input voltage is too low.
• Medium double blink indicates sensor is outside the operating temperature range.
• Fast blink indicates the signal drifted below 4 mA and needs to be re-calibrated, only in non-filtered output run mode (no dead-band).
Red mA Fault LED attempts to output .5 mA fault signal
• Fast blink indicates 4/20 mA loop failure or load resistance too high
Green Source LED
• One blink every 2 seconds indicates when source is energized and also that the source is not short circuited.
Green ATMOS LED
• Continuous ON indicates ATMOS circuitry is active or adjusting the enclosure’s internal environmental conditions for the sensor to function reliably.
NOTES:
• If the Source LED isn’t blinking,
do not
proceed until the condition is corrected.
• If a Fault LED is lighted, immediately refer to
Fault Indicator Error Sequences (page 11) to
determine potential problem. Do not attempt calibration if a Fault is indicated.
• All status LED’s are subordinate to Fault indicators.
• If an LED is indicated as OFF, it must actually be
OFF for proper sensor operation.
• If an LED status is N/A (not applicable), that LED indication may vary depending on other operational factors.
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Operation
continued
Figure 7: LED Indicator Summary
See LED indicators and blink sequence descriptions on page 9.
Normal Run Mode
= Initiated by button press
G
= Green LED
4/20 mA Loop Test Mode
Y
= Yellow LED
R
= Red LED
LED
WITH OUTPUT
FILTERING 1
WITHOUT OUTPUT
FILTERING 2
POWER G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
OFF
OFF
OFF
OFF
OFF
OFF
SOURCE G
ATMOS G
ON PERIODICALLY 3 ON PERIODICALLY 3
NOTE 1: Dead-band from 4 mA to 4.6 mA
NOTE 2: No dead-band from 0 to 26 mA
NOTE 3: Environmental compensation energized for cold temperatures
Calibration Mode
LED
4/20 mA LOOP TEST
(22 mA HIGH) 1
4/20mA LOOP TEST
(.5 mA LOW) 1
POWER G
SYSTEM Y
OFF OFF
CALIBRATE Y
FAULT R
N/A N/A mA FAULT R
N/A N/A
SOURCE G
N/A N/A
ATMOS G
N/A N/A
NOTE 1: Error on output will result in fast blink on red mA FAULT LED.
LED
ZERO FUNCTION
INITIATED 1
DURING SPAN
CALIBRATION
DURING 4 mA
OUTPUT CALIBRATION
FACTORY CALIBRATION
LOST 2
POWER G
SYSTEM Y
N/A
CALIBRATE Y
N/A
FAULT R
OFF OFF N/A N/A mA FAULT R
OFF OFF OFF N/A
SOURCE G
N/A N/A N/A N/A
ATMOS G
N/A N/A N/A N/A
NOTE 1: Indicates that “Zero” function is initiated and pushbutton S1 can be released. Yellow Calibrate LED will be off after pushbutton is released.
NOTE 2: Indicates unit lost the factory calibration data. Contact Manning Systems.
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Operation
continued
Figure 7: LED Indicator Summary, continued
See LED indicators and blink sequence descriptions on page 9.
Fault Indicator Error Sequences
= Initiated by button press
G
= Green LED
Y
= Yellow LED
R
= Red LED
LED
LOST FACTORY
CALIBRATION 1
FAILED 4/20 mA
OUTPUT 2
LOW SIGNAL OR
FAILED SOURCE OR CIRCUIT
POWER SUPPLY
VOLTAGE TOO LOW
POWER
G
SYSTEM
Y
CALIBRATE
Y
FAULT
R mA FAULT
R
SOURCE
G
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
ATMOS
G N/A N/A N/A N/A
NOTE 1: Indicates Normal Run Mode wthout output filtering where unit lost factory calibration data. Contact Manning Systems for technical support.
NOTE 2: Indicates failed 4/20 mA output signal. Load resistance is too high.
OPERATING TEMPERATURE
RANGE EXCEEDED
N/A
N/A
N/A
N/A
N/A
LED
READING DRIFTED
BELOW 4 mA 1
SHORTED
SOURCE
POWER G
SYSTEM Y N/A N/A
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
N/A
N/A
N/A
N/A
N/A
OFF
ATMOS G N/A N/A
NOTE 1: Indicates the gas reading drifted below 4 mA and needs to be
re-calibrated only in non-filtered output run mode (no dead-band).
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3
Operation
continued
C
Modes of Operation
The AirScan TM calibration: iR has various modes of operation and
• Normal run mode with output filtering
• Normal run mode without output filtering
• 4/20 mA loop check
• 4/20 mA calibration to an external PLC or read-out panel
• Neutral gas resting point or “zero” calibration mode
• Span calibration modes
Normal Run Modes
Normal run mode with output filtering
This mode outputs a signal from 4 to 27 mA with a
“dead band” from 4 to 4.6 mA. This “dead band” masks small environmental anomalies that could facilitate output signal fluctuations or transients around the 4 mA resting point when the unit is not sensing target gas.
Start:
If the “system” LED is blinking slowly, press and hold both S1 and S2 simultaneously for 1 second or more until the “system” LED is continuous ON, then release both buttons. If the “system” LED is blinking fast, this mode cannot be engaged and the factory needs to be contacted. See the following example.
SEQUENCE LED
POWER
G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT
R
SOURCE G
ATMOS G
OFF
OFF
OFF
N/A
LED
POWER G
SYSTEM
Y
CALIBRATE
Y
FAULT R mA FAULT R
SOURCE G
ATMOS G
Normal run mode without output filtering
This mode outputs a signal that nominally rests at 4 mA and can range continuously from 0 to 27 mA. Any subtle changes in sensor response will be sent to the mA loop output. This mode is entered automatically when the calibration modes are activated. Some users may wish to see the subtle anomalies in the signal near the nominal 4 mA rest area.
Start:
If the “system” LED is continuous ON, press and hold both S1 and S2 simultaneously for 1 second or more until the “system” LED is blinking slowly then release both buttons to enter this mode. If the “system”
LED is blinking fast this mode is always engaged and can only be exited by fully calibrating the unit. See the following example.
SEQUENCE
OFF
OFF
OFF
N/A
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Operation
continued
4/20 mA Loop Test
{22 mA full-scale and .5 mA fault check}
Start:
Press S1 5 times within a two to three second period of time. The yellow “system” LED will turn off and the yellow “calibrate” LED will blink fast. See the following example. Output should be 21 to 22.5 mA.
22 mA Full Scale Output Test
SEQUENCE LED
POWER
G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
OFF
N/A
N/A
N/A
N/A
To proceed to the next step in the mA test, press and hold S1 for 1 second or more until the yellow “calibrate”
LED is a medium double blink. See the following example. The output should be between .4 and .6 mA.
.5 mA Fault Output Test
LED SEQUENCE
POWER G
SYSTEM
Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS G
OFF
N/A
N/A
N/A
N/A
Exit:
Press and hold S1 for 1 second or more until the yellow “system” LED resumes the state before the mA test was initiated and the yellow “calibrate” LED turns off.
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Operation
continued
LED
POWER
G
SYSTEM
Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS
G
Calibration/Programming Modes:
Refer to Calibration, Section D before proceeding.
Auto “ZERO” Program Function
Start:
Press and hold S1 for 1 second or until the yellow
“calibrate” LED turns continuous ON. Release S1 and the yellow “calibrate” LED will turn off. This indicates the unit
“zero” is now programmed to a neutral or 4 mA resting state for
0 ppm of target gas.
LED SEQUENCE
POWER G
SYSTEM
Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS G
N/A
OFF
OFF
N/A
N/A
“Span” Calibration/Programming Mode
Start:
Press and hold S2 for 1 second or until the yellow
“system” LED blinks slowly and the yellow “calibrate”
LED blinks fast. Once in this mode the “span” pot can be adjusted to determine the 20 mA full-scale concentration.
SEQUENCE
OFF
OFF
N/A
N/A
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Exit:
To program the “span” setting and exit this mode, press and hold S2 for 1 second or until the yellow
“system” LED resumes the state before the calibration mode was initiated and the yellow “calibrate” LED turns off.
4 mA Output Calibration/Programming Mode
Start:
Press and hold S1 for 7 seconds or until the yellow
“system” LED turns continuous ON and the yellow
“calibrate LED blinks slowly. See the following example.
Once in this mode the “zero” pot can be adjusted to calibrate the 4 mA output to a PLC, SCADA system, panel, etc.
LED SEQUENCE
POWER G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT
R
SOURCE G
ATMOS G
N/A
OFF
N/A
N/A
Exit:
To program the 4 mA calibration point and exit this mode, press and hold S1 for 1 second or until the yellow “system” LED resumes the state before the calibration mode was initiated and the yellow “calibrate”
LED turns off.
14
3
Operation
continued
D
Calibration
Before calibrating the unit, ensure the startup procedure was followed and unit was powered on for a minimum of 12 hours (with the enclosure door closed) in the operating environment.
IMPORTANT NOTE:
For environments where the ambient temperature is less than 10° F, during the calibration procedure, the door must be closed as far as possible.
This will ensure the sensor temperature will not drop below the minimum operating temperature which could adversely affect the programmed calibration parameters.
There are only two adjustment pots and two pushbuttons on the main board that are used for programming the calibration parameters. See Section B, Pushbutton
Operation, LED Indicators, Adjustment Pots and Test
Points. Use Section B to familiarize yourself with the pushbuttons S1, S2, adjustment pots “zero”, “span”,
Test(+), Test(–) and their locations on the main board
(see Figure 8).
Figure 8: Board Component Layout
Zero Adjust
Span Adjust
ICSP Programming Port
Pushbutton S1
Pushbutton S2
Serial Port
Rx LED Tx LED
JP3 JP2
ZERO
S1
SPAN
S2
JP1
SIG
+24
GND
SHLD
TEST +
TEST -
Draw
Chamber
POWER
SYSTEM
CALIBRATE
FAULT mA FAULT
IR SOURCE
ATMOS
ACTIVE
LED
POWER G
SYSTEM Y
CALIBRATE
Y
FAULT R mA FAULT R
SOURCE G
ATMOS G
In addition, the LED indicators and blink pattern meanings are also summarized in this section. The calibration procedure will require use and knowledge of the following tools within the sensor:
• “Zero” adjustment pot – adjusts output calibration of the 4 mA nominal resting point
• “Span” adjustment pot – adjusts the 20 mA concentration level or unit span/sensitivity
• Pushbutton S1 – used to initiate the auto-zero function and program the 4 mA output calibration
• Pushbutton S2 – used to program the span setting
In addition, there are four LED’s used in the calibration procedure. Yellow “system” and “calibrate”, and red
“fault” and “mA fault” LED’s located on the main board are utilized as status indicators during the calibration procedure and as diagnostic and trouble indicators.
Non-calibrated Sensor or Loss of Factory Calibration
IMPORTANT:
Upon power up, if the yellow “system”
LED is showing a fast blink pattern, the unit hasn’t been calibrated yet or has lost the factory calibration and requires a
full
calibration before it can reliably read the target gas. See the following example. Should this occur, please contact Manning Systems for assistance!
SEQUENCE
N/A
N/A
N/A
N/A
N/A
Tubing to calibration point
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3
Operation
continued
LED
POWER G
SYSTEM Y
CALIBRATE Y
FAULT
R mA FAULT R
SOURCE G
ATMOS G
Before continuing with the calibration procedure, determine which of the two Normal output modes is best for the control scheme. Filtered output holds a stable 4 mA signal within a dead-band range while the non-filtered output allows the signal to be seen without any output limitations.
After this output mode choice is made, continue through Steps 1–3 of the Calibration Procedure. As a first step, the 4 mA output is matched to the signal input device being used as a control panel. After this is accomplished, Step 2 (Zero Calibration) and Step 3
(Span Calibration) can be completed in that order.
Filtered Output Mode
Each unit is equipped with a filtered output or “dead band” output mode which locks the output at 4 mA for signal readings of 4 to 4.6 mA. This masks surrounding abrupt adverse environmental transients that would cause a small short-term anomaly on the 4 mA resting point for a near 0 ppm reading of the target gas. In this mode, the yellow “system” LED will be ON. See the following example.
SEQUENCE
OFF
OFF
OFF
N/A
Non-Filtered Output Mode (no signal deadband)
Start:
Press and hold both the “zero” (S1) and “span”
(S2) buttons simultaneously for one second or until the
“system” LED begins to blink slowly. See example below.
This mode will allow any anomalies to be transmitted from 0 to 27 mA on the output. This mode is also used in the upcoming Simple Zero Test procedure.
LED
POWER G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
SEQUENCE
OFF
OFF
OFF
N/A
Exit:
To revert back to “dead band” mode, repeat the same button press procedure above. This button press sequence will toggle between modes (filtered to nonfiltered).
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3
Operation
continued
STEP 1
4-20 mA Output Calibration
This procedure calibrates the 4/20 mA output to match a
PLC input converter or various devices that interpret the
4/20 mA signal output to ensure the 4 mA output rests at a true 4 mA even with minor mismatches in load resistance, long feed wiring, or adverse environmental conditions.
Start:
Set meter to mV DC and place meter leads on
Test(+) and Test(–) respectively (see Figure 9).
• Press and hold the “zero” button (S1) for 5 seconds or until the “calibrate” LED is blinking slowly and the “system” LED is continuous ON. Make sure the
“mA Fault” LED is OFF.
• Adjust the zero potentiometer until the output reads 3.99 to 4.01 mA (39.9 to 40.1 mV). This sets the 4 mA resting point. Make small adjustments and wait for the output to change because adjustment response is delayed between source pulses.
4 mA output programming calibration mode
LED
POWER
G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
SEQUENCE
N/A
OFF
N/A
N/A
Exit:
Press and hold the “zero” button (S1) for one second or more until the “calibrate” LED turns off.
The “system” LED will resume the previous state, either
“filtered” or “non-filtered” output mode. This indicates the parameters are now programmed into memory.
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STEP 2
Zero Calibration
This procedure sets the internal reference that is indicative of 0 ppm of target gas.
It MUST be performed before proceeding or every other setting will be offset and inaccurate.
The “zero” can be initiated at any time as long as a neutral gas is flowing through the calibration port or the surrounding air is known to be FREE of any target gas down to 1 ppm.
Start:
Apply
pure nitrogen
(N
2
) into the calibration port at a rate of .6 liter/min. for at least 3 minutes (OR until output signal is within ± .02 mA of signal deviation/change).
• Press and hold the “zero” button (S1) for approximately 1 second or until the yellow “calibrate” LED is continuous ON.
• When yellow calibration LED is continuous ON, release the “zero” button. The “calibrate” LED will turn off and the unit will be zeroed. See example below.
“Zero” programming calibration mode
LED SEQUENCE
POWER G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
N/A
OFF
OFF
N/A
N/A
Exit:
System will automatically resume previous mode, either “normal” or “no dead band” mode. This indicates the parameters are now programmed into memory.
Place multi-meter leads on Test(+) and Test(–) and ensure the output is steadily resting between 3.9 to
4.1 mA (see Figure 9 on next page). If this isn’t the case, initiate the auto “zero” procedure once again.
17
3
Operation
continued
Figure 9: Board Component Layout
Zero Adjust
Span Adjust
ICSP Programming Port
Pushbutton S1
Pushbutton S2
Serial Port
Rx LED Tx LED
JP3 JP2
Note 1: Checking voltage to sensor at +24 and GND
24
VDC
ZERO
S1
SPAN
S2
Draw
Chamber
Black
-
Red
+
Note 2: Reading signal at TEST+ and TEST-
40-200 mVDC
JP1
SIG
+24
GND
SHLD
TEST +
TEST -
POWER
SYSTEM
CALIBRATE
FAULT mA FAULT
IR SOURCE
ATMOS
ACTIVE
Black
-
Red
+
Tubing to calibration point
STEP 3
Span Calibration
This procedure sets the “span” or concentration level that would depict a 20 mA reading for full-scale target gas on the 4/20 mA output. The lower the target gas concentration is for a span of 20 mA, the more sensitive or responsive the unit would be to lower ppm readings.
NOTE:
This procedure should only be performed if the zero and 4/20 mA procedures are successfully completed.
Start:
Set meter to mV DC, place meter leads on
Test(+) and Test(–) respectively (see Figure 9).
Apply
pure nitrogen
(N
2
) into the calibration port at a rate of .6 Liter/min. for at least 3 minutes (OR until output signal has stabilized to within ± .02 mA of signal deviation/change). If N
2
is currently flowing from previous
“zero” calibration, disregard the additional flow time.
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Press and hold the “span” button (S2) for 1 second or more until the yellow “calibrate” LED blinks fast and the yellow “system” LED is blinking slowly. See the following example.
SEQUENCE LED
POWER
G
SYSTEM
Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
OFF
OFF
N/A
N/A
Ensure the output rests between 3.9 and 4.1 mA (39.0 to 41.0 mV). If this is not the case, perform the “zero” procedure again.
Once the output is within the required range with nitrogen flowing, apply
full-scale
target gas into the calibration port at a rate of .6 liters/min for 3 minutes immediately following the nitrogen flow.
If the signal is 26 mA or greater, adjust the “span” potentiometer counter-clockwise until the signal is near
20 mA.
Because there is a slight delay in potentiometer movement, make small adjustments and wait for the output to change because adjustment response is delayed between source pulses.
Wait until the output signal has stabilized to within ± .02 mA of signal deviation/change. Adjust the “span” potentiometer again until the output reads around 20 mA.
Exit:
Press and hold the “span” button (S2) for one second or more until the yellow “calibrate” LED turns off. The yellow “system” LED will resume the previous state, either “filtered” or “non-filtered” output mode.
This indicates the parameters are now programmed into memory.
18
3
Operation
continued
E
Procedures
Simple Zero Test
This test will ensure the unit is calibrated for a true
“zero” and duly represents an absence of target gas in this condition.
Start:
Set meter to mV DC, place meter leads on
Test(+) and Test(–) respectively (see Figure 9).
• Apply (N
2
) into the calibration port at a rate of .6 Liter/min. for at least 3 minutes.
Check the status of the yellow “system” LED.
If this LED is continuous ON, place the unit in non-filtered output run mode by pressing both the
“zero” (S1) and “span” (S2) buttons simultaneously for 1 second or until the “system”
LED begins to blink slowly. See example below.
• Wait until output signal has stabilized to within
± .02 mA of signal deviation/change.
• Output should read between 3.9 and 4.1 mA
(39.0 to 41.0 mV).
If this is not the case, proceed to the next step.
• Follow the “zero” procedure above to re-zero the unit
• Follow the “simple zero test” procedure to ensure the unit is resting at the optimum 4 mA point.
Simple “Zero” test – NO “Dead-band” mode 0 to 26 mA
LED SEQUENCE
POWER G
SYSTEM
Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS
G
OFF
OFF
OFF
N/A
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LED
POWER G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE
G
ATMOS G
Exit:
Press and hold both the “zero” (S1) and “span”
(S2) buttons simultaneously for 1 second or more until
“system” LED is continuous ON. Unit should be ready for long-term operation.
4/20 mA Output Loop Integrity Check
22 mA High Signal Test
STEP 1
Start:
Set meter to mV DC, place meter leads on
Test(+) and Test(–) respectively (see Figure 9).
• Press the “zero” (S1) button 5 times. The yellow
“calibrate” LED will blink fast and the yellow
“system” LED will turn off. The output should be
21 to 22.5 mA (210 to 225 mV).
If a problem exists on the output signal line, or the output load is not within the specified range, the “mA fault” LED will blink either before or upon activation of this test. In some cases the 22 mA high signal output will cause incorrect output load resistance values to surface because of the demand on high resistances to produce high currents.
Low power supply voltages can also be something to investigate if this error surfaces only when the 22 mA high test is initiated.
During 4/20 mA loop test (22 mA high)
SEQUENCE
OFF
N/A
N/A
N/A
N/A
19
3
Operation
continued
During 4/20 mA loop test (22 mA high) w/ Error on output
SEQUENCE LED
POWER G
SYSTEM Y
CALIBRATE Y
FAULT
R mA FAULT R
SOURCE G
ATMOS G
OFF
N/A
N/A
N/A
.5 mA Low Signal Output Test for
Fault Conditions
NOTE:
The unit must be in the 4/20 mA loop (22 mA high) test to proceed with this test.
STEP 2
Start:
Press and hold the “zero” (S1) button for at least one second or until the yellow “calibrate” LED shows medium double blink. The yellow “system” LED will remain off and the output should change to .4 to .6 mA
(4 to 6 mV).
If a problem exists on the output signal line, or the output load is not within the specified range, the “mA fault” LED will blink either before or upon activation of this test.
If an error surfaces during this test only, the possibility of cross-talk can exist on the signal line. This is caused by resistive shorts to power or other voltage sources that can raise the .5 mA target current on the line.
Moisture in the connector can cause stray voltage to migrate from the 24V DC pin over to the 4/20 mA signal line. Check connectors or refer to the troubleshooting section or error code analysis section for assistance.
During 4/20 mA loop test (.5 mA low)
SEQUENCE LED
POWER G
SYSTEM Y
CALIBRATE
Y
FAULT R mA FAULT R
SOURCE G
ATMOS
G
OFF
N/A
N/A
N/A
N/A
During 4/20 mA loop test (.5 mA low) with Error
LED SEQUENCE
POWER
G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS
G
OFF
N/A
N/A
N/A
STEP 3
Exit:
Press and hold the “zero” (S1) button for at least one second or until the yellow “calibrate LED turns off.
The yellow “system” LED will resume the previous state, either “filtered” or “non-filtered” output mode.
NOTE:
In addition to test procedures initiated manually, every 2 seconds SensorCheck
TM
technology monitors several performance parameters of the AirScan TM iR. A notification of .5 mA on the output signal is transmitted if any of these parameters is not met.
20 Manning AirScan-iR Refrigerant Sensor
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3
Operation
continued
F
Troubleshooting
Electrical Interference
This sensor has been designed to be highly resistant to
EMI/RFI using multiple stages of filtering and protection. However, in extreme environments, some noise pickup can occur directly through the sensor.
Insure that the bare shield wire of the instrument cable is properly connected at the readout unit. See Figure 10,
Note 2 for AirScan TM iR meter test points.
Figure 10: Troubleshooting the AirScan
TM iR
Zero Adjust
Span Adjust
ICSP Programming Port
Pushbutton S1
Pushbutton S2
Serial Port
Rx LED Tx LED
JP3 JP2
Note 1: Checking voltage to sensor at +24 and GND
24
VDC
ZERO
S1
SPAN
S2
Draw
Chamber
Black
-
Red
+
Note 2: Reading signal at TEST+ and TEST-
40-200 mVDC
JP1
SIG
+24
GND
SHLD
TEST +
TEST -
POWER
SYSTEM
CALIBRATE
FAULT mA FAULT
IR SOURCE
ATMOS
ACTIVE
Sensor On-board Diagnostic System
It is possible to have the mA output fail during normal run mode. In some instances a mA output circuit that is incorrectly setup can supply 4 mA to the load reasonably well; however, an incorrect circuit arrangement could not be capable of driving 20 mA to the load when required. Therefore, the system will place a fault condition out on the mA loop output and flash the “mA fault” LED indicating the output wiring is not correct or load resistance is too high.
To properly ensure the load is correct, during the 20 mA or (high) 4/20 mA integrity test, the output circuit dynamic range is tested to its fullest extent. If the mA fault LED blinks during this test, the load resistance is too high or power supply voltage is too low.
In the case of a mA Failure during Run mode, the “mA fault” LED will blink Fast.
In the case of a mA failure during the mA output test, the “mA fault” LED will also blink Fast. See figure at the top of the next page.
Black
-
Red
+
Tubing to calibration point
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3
Operation
continued
Error on 4/20 mA output or during 4/20 mA test 20 mA high
LED
POWER G
SYSTEM Y
CALIBRATE Y
FAULT
R mA FAULT R
SOURCE G
ATMOS G
SEQUENCE
N/A
N/A
N/A
N/A
To resolve this issue, Place a resistor having at least 100 to 250 ohms across the signal output (SIG) and ground
(GND). The “mA fault” LED will stop blinking indicating the load or wiring has a problem.
Sensor Output at 0 mA
Verify +24 VDC at the sensor terminal block (see Figure
10, Note 1 on previous page).
Check signal voltage between Test(+) and Test(–) (see
Figure 10, Note 2). Voltage should be in the range of 40 to
200 mV corresponding to an actual current flow of 4 to 20 mA. If this voltage is 0 mV, the signal has no path to ground. Check monitoring equipment connections and configuration. Input impedance must be 500 ohms or less.
Sensor Output at .5 mA
Please see Section D on page 15 for possible fault
conditions related to .5 mA output.
Gas Concentration Indicated With No Refrigerant Present
TM
The AirScan iR is designed to be quite specific to
CFC/HCFC/HFC’s that are colorless, odorless gases which can’t be sensed by humans at low levels. Always double-check with another instrument before assuming refrigerants are not present.
Performing a zero and a span calibration using certified calibration gas will confirm or correct the sensor’s reading.
LED
POWER
G
SYSTEM Y
CALIBRATE Y
FAULT R mA FAULT R
SOURCE G
ATMOS
G
IR Source Failure
If the IR source signal strength drops to the point that the unit can no longer function satisfactorily, the “fault”
LED will remain continuous ON and the 4/20 mA output will be set to 0.5 mA. See example below. This condition can also occur in environments where there is a significant amount of particulate contamination.
Usually is takes an appreciable amount of time for the particles to pose signal degradation, however, under long-term exposure the filter surface could be dirty causing low thermal readings, hence marginal operation for signal analysis.
SEQUENCE
N/A
N/A
N/A
N/A
N/A
NOTE:
4/20 mA will be set to 0.5 mA.
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4
Maintenance
Expose each sensor to test gases monthly to verify that the sensor has a normal response. This will also check the alarm lights and relay action of the monitoring equipment.
It is essential that signal voltages be taken and logged on a consistent basis at least monthly. Periodically, sensors should be exposed to refrigerant sample and the results logged.
For proper operation it is essential that the test and calibration schedule be adhered to. Manning Systems recommends the following maintenance schedule:
• Calibration should be performed with certified calibration gas every six months. Calibration kits are available from Manning Systems.
• All tests and calibrations must be logged. It is highly recommended that certified calibration gas be used every six months.
5
Replacement Parts
For replacement parts, contact Manning Systems. Be sure to give serial number of unit and model number.
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23
6
Limited
1.
Limited
Manning Systems, Inc. (“Manning”) warrants to the original purchaser and/or ultimate customer
(“Purchaser”) of Manning’s Products (“Product”) that if any part thereof proves to be defective in material or workmanship within eighteen (18) months of the date of shipment by Manning or twelve (12) months from the date of first use by the purchaser, whichever comes first, such defective part will be repaired or replaced, free of charge, at Manning’s discretion if shipped prepaid to Manning at 11511 W. 83rd Terrace, Lenexa,
Kansas 66214, in a package equal to or in the original container. The Product will be returned freight prepaid and repaired or replaced if it is determined by Manning that the part failed due to defective materials or workmanship. The repair or replacement of any such defective part shall be
Manning’s sole and exclusive responsibility and liability under this limited warranty.
2.
Exclusions
A. If gas sensors are part of the Product, the gas sensor is covered by a twelve (12) month limited warranty of the manufacturer.
B. If gas sensors are covered by this limited warranty, the gas sensor is subject to inspection by Manning for extended exposure to excessive gas concentrations if a claim by the Purchaser is made under this limited warranty. Should such inspection indicate that the gas sensor has been expended rather than failed prematurely, this limited warranty shall not apply to the Product.
C. This limited warranty does not cover consumable items, such as batteries, or items subject to wear or periodic replacement, including lamps, fuses, valves, vanes, sensor elements, cartridges, or filter elements.
3.
Warranty Limitation and Exclusion
Manning will have no further obligation under this limited warranty. All warranty obligations of
Manning are extinguishable if the Product has been subject to abuse, misuse, negligence, or accident or if the Purchaser fails to perform any of the duties set forth in this limited warranty or if the Product has not been operated in accordance with instructions, or if the Product serial number has been removed or altered.
4.
Disclaimer of Unstated Warranties
THE WARRANTY PRINTED ABOVE IS THE ONLY
WARRANTY APPLICABLE TO THIS PURCHASE.
ALL OTHER WARRANTIES, EXPRESS OR
IMPLIED, INCLUDING, BUT NOT LIMITED TO,
THE IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A
PARTICULAR PURPOSE ARE HEREBY
DISCLAIMED.
5.
Limitation of Liability
IT IS UNDERSTOOD AND AGREED THAT
MANNING’S LIABILITY, WHETHER IN
CONTRACT, IN TORT, UNDER ANY WARRANTY,
IN NEGLIGENCE OR OTHERWISE SHALL NOT
EXCEED THE AMOUNT OF THE PURCHASE
PRICE PAID BY THE PURCHASER FOR THE
PRODUCT AND UNDER NO CIRCUMSTANCES
SHALL MANNING BE LIABLE FOR SPECIAL,
INDIRECT, OR CONSEQUENTIAL DAMAGES.
THE PRICE STATED FOR THE PRODUCT IS A
CONSIDERATION LIMITING MANNING’S
LIABILITY. NO ACTION, REGARDLESS OF
FORM, ARISING OUT OF THE TRANSACTIONS
UNDER THIS WARRANTY MAY BE BROUGHT BY
THE PURCHASER MORE THAN ONE YEAR
AFTER THE CAUSE OF ACTIONS HAS
OCCURRED.
Manning AirScan-iR Refrigerant Sensor
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Key features
- Infrared technology
- Linear 4/20 mA output
- SensorCheck technology
- Diffusion sampling
- Environmental compensation