Det-Tronics X5202 User manual
1.1 95-8788
Instructions
UVIR Flame Detector
X5202
Table of Contents
DESCRIPTION..............................1
Outputs ................................1
LED ...................................2
oi
(Optical Integrity) ......................2
Communication ..........................3
Data Logging ............................3
Integral Wiring Compartment ................3
SIGNAL PROCESSING OPTIONS ..............3
IR Detector Options .......................3
UV Detector Options ......................4
GENERAL APPLICATION INFORMATION.........4
Response Characteristics ..................4
False Alarm Sources ......................5
Factors Inhibiting Detector Response .........5
IMPORTANT SAFETY NOTES..................6
INSTALLATION..............................7
Detector Positioning .......................7
Detector Orientation .......................7
Protection Against Moisture Damage ..........8
Wiring Procedure .........................8
Setting Device Network Addresses
(EQ and EQP Models Only) ............14
STARTUP PROCEDURE .....................15
Fire Alarm Test ..........................15
TROUBLESHOOTING .......................15
MAINTENANCE ............................16
Cleaning Procedure ......................16
oi
Reector Plate Removal and Replacement ..16
Periodic Checkout Procedure ...............17
Clock Battery ...........................17
FEATURES................................17
SPECIFICATIONS ..........................18
REPLACEMENT PARTS .....................20
Replacement Parts List ...................20
DEVICE REPAIR AND RETURN ...............20
ORDERING INFORMATION ..................20
Accessories ............................20
X5202 Series Model Matrix ................21
APPENDIX A – FM APPROVAL AND
PERFORMANCE REPORT ...................22
APPENDIX B – CSA APPROVAL ...............26
APPENDIX C – ATEX APPROVAL ..............27
APPENDIX D – IECEx APPROVAL .............29
APPENDIX E – DECLARATION OF CONFORMITY ..30
1
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1. 1
IMPORTANT
Be sure to read and understand the entire
instruction manual before installing or operating
the ame detection system. Any deviation from
the recommendations in this manual may impair
system performance and compromise safety.
ATTENTION
The X5202 includes the Automatic
oi
®(Optical
Integrity) feature — a calibrated performance test
that is automatically performed once per minute
to verify complete detector operation capabilities.
Testing with an external test lamp is not
approved or required.
DESCRIPTION
The X5202 UVIR Flame Detector provides reliable
detection of fires that are comprised of hydrogen,
methanol and propane. The detector has Division and
Zone explosion-proof ratings and is suitable for use in
indoor and outdoor applications.
The standard output configuration includes fire, fault and
auxiliary relays. Output options include:
– 0 to 20 mA output (in addition to the three relays)
– Eagle Quantum Premier®(EQP) compatible model
(no analog or relay outputs)
– HART communication
A tri-color LED on the detector faceplate indicates
normal condition and notifies personnel of fire alarm or
fault conditions.
Heated optics on the IR channel increase resistance to
moisture and ice.
The detector housing is available in copper-free aluminum
or stainless steel, with Type 4X and IP66/IP67 rating.
OUTPUTS
Relays
The standard detector is furnished with fire, fault, and
auxiliary relays. All three relays are rated 5 amperes at
30 Vdc.
The Fire Alarm relay has redundant terminals and
normally open / normally closed contacts, normally
de-energized operation, and latching or non-latching
operation.
The Fault relay has redundant terminals and normally
open contacts, normally energized operation, and
latching or non-latching operation.
INSTRUCTIONS
UVIR Flame Detector
X5202
©2020 Detector Electronics Corporation
Last Manual Update: 5/20/2019
95-8788
21. 1
The Auxiliary relay has normally open / normally
closed contacts, and is configurable for energized or
de-energized operation, and latching or non-latching
operation.
0 to 20 mA Output
A 0 to 20 mA output is available as an option (in addition
to the three relays). This option provides a 0–20 mA dc
current output for transmitting detector status information
to other devices. The circuit can be wired in either an
isolated or non-isolated configuration and can drive
a maximum loop resistance of 500 ohms from 18 to
19.9 Vdc and 600 ohms from 20 to 30 Vdc. Table 1
indicates the detector status conditions represented by
the various current levels. The output is calibrated at the
factory, with no need for field calibration. A model with
relays and 0–20 mA with HART is also available. Refer to
Addendum number 95-8636 for complete details.
NOTE
The output of the 0–20 mA current loop is not
monitored by the fault detection circuitry of the
detector. Therefore, an open circuit on the loop will
not cause the fault relay to change state or the
detector status LED to indicate a fault.The status of
the LED always follows the status of the relays.
An alarm condition will normally over-ride a fault condition,
unless the nature of the fault condition impairs the ability
of the detector to generate or maintain an alarm output,
e.g., loss of operating power, complete blockage of the
detectors optics, or internal failure.
LON/SLC Output
The EQP model is designed for use exclusively with
the Det-Tr
onics Eagle Quantum Premier system. The
detector communicates with the system controller over
a digital communication network or LON/SLC (Local
Operating
Network / Signaling Line Circuit). The LON/
SLC is a fault tolerant, two wire digital communication
network arranged in a loop configuration. Analog and
relay outputs are not available on this model.
LED
A tri-color LED on the detector faceplate indicates
normal condition and notifies personnel of fire alarm
or fault conditions.
Table 2 indicates the condition of the
LED for each status.
oi
(OPTICAL INTEGRITY)
Automatic
oi
The X5202 includes the Automatic
oi
feature — a
calibrated performance test that is automatically
performed once per minute to verify complete detector
operation capabilities. No testing with an external test
lamp is required. The detector automatically performs
the same test that a maintenance person with a test
lamp would perform — once every minute, 60 times per
hour. However, a successful Automatic
oi
test does not
produce an alarm condition.
Table 1—Detector Status Conditions Indicated by Current Level
Current Level (±0.3 mA) Detector Status
0 mA Power Fault
1 mA General Fault
2 mA oiFault
4 mA Normal Operation
8 mA IR Pre-Alarm only
12 mA UV Alarm only
14 mA IR Alarm only
16 mA Pre-Alarm
20 mA Fire Alarm
Table 2—Detector Status Indicator
Detector Status LED Indicator
Power On/Normal Auto
oi
(no fault or fire alarm) Green
Power On/Normal Man
oi
Green, flashing off for 0.5 sec.
every 5 sec.
Fault Yellow
UV Alarm only Red, flashing on for
0.5 sec. and off for 0.5 sec.
IR Alarm only Red, flashing on for
0.25 sec. and off for 0.25 sec.
Pre-Alarm Red, flashing on for
1 sec. and off for 1 sec.
Fire (Alarm) Steady Red
On Power-Up, The LED Flashes in Sequence as Follows,
Indicating Sensitivity and Signal Processing Status
High UV Sensitivity
Very High UV Sensitivity
Three Red Flashes
Four Red Flashes
Stand. UV Signal Process.
Arc Rej. UV Signal Process.
One Yellow Flash
Two Yellow Flashes
High IR Sensitivity
Very High IR Sensitivity
Three Green Flashes
Four Green Flashes
Quick Fire/TDSA IR Signal
TDSA only IR Signal
One Yellow Flash
Two Yellow Flashes
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The detector signals a fault condition when less than half of
the detection range remains. This is indicated by the Fault
output and is evident by the yellow color of the LED on the
face of the detector. See the "Troubleshooting" section for
further information.
Magnetic oi/ Manual oi
The detector also incorporates both Magnetic oi(Mag
oi)and Manual oi(Man oi)features that provide
the same calibrated test as the Automatic oi, and in
addition actuates the Alarm output to verify operation for
preventive maintenance requirements. These features
can be performed at any time and eliminate the need for
testing with a non-calibrated external test lamp.
CAUTION
These tests require disabling of all extinguishing
devices to avoid release resulting from a successful
test.
The Mag oitest is performed by placing a magnet at the
location marked "MAG OI" on the outside of the detector
(see Figure 2). The Man oitest is accomplished by
connecting the oilead (terminal 22) to power supply minus
via an external switch. The magnet or switch must be held
in place for a minimum of 6 seconds to complete the test.
Either of these test methods activates the calibrated UV
and IR emitters. If the resulting signal meets the test criteria,
indicating that greater than half of the detection range
remains, the fire alarm output of the detector is activated.
On models with relay, 0–20 mA, or HART outputs, this
condition remains until the magnet is removed or the switch
is released, regardless of whether the detector has been
configured for latching or non-latching operation. The fire
alarm output condition stays active for three seconds on
Eagle Quantum Premier models.
If less than half of the detection range remains, no alarm
is produced and a fault is generated. The fault indication
can be reset by momentarily applying the Mag oior Man
oiswitch. In this case, the detector's optics should be
cleaned and the oitests should be repeated. See the
"Cleaning Procedure" section of this manual for details.
NOTE
Refer to Appendix A for FM verification of the
oi
function.
COMMUNICATION
The detector is furnished with an RS-485 interface for
communicating status and other information with external
devices. The RS-485 supports Modbus protocol, with the
detector configured as a slave device.
For HART communication, connect a HART communicator
across a 250 ohm resistor in the 0-20 mA loop. HART output
models do not support RS-485 Modbus protocol.
NOTE
The EQP model uses LON/SLC communication. RS-485
and HART communication are not available on the EQP
model.
DATA LOGGING
Data logging capability is also provided. Status conditions
such as normal, power down, general and oifaults, pre-
alarm, fire alarm, time and temperature are recorded.
Each event is time and date stamped, along with the
temperature and input voltage. Event data is stored in
non-volatile memory when the event becomes active
and again when the status changes. Data is accessible
using the Inspector Connector accessory, RS-485, or the
EQP Controller.
INTEGRAL WIRING COMPARTMENT
All external wiring to the device is connected within
the integral junction box. The detector is furnished with
four conduit entries, with either 3/4 inch NPT or M25
threads.
SIGNAL PROCESSING OPTIONS
The X5202 features signal processing options for both the
UV and IR sensor. These options determine the type of
logic that the detector will use for processing fire signals
to customize the detector to the application.
IR DETECTOR OPTIONS
The IR detector in the X5202 can be programmed for:
– TDSA enabled
– Both TDSA and Quick Fire enabled (either initiates
fire alarm)
Time Domain Signal Analysis (TDSA)
The TDSA signal processing technique analyzes the
input signal in real time, requiring the IR signal to flicker
randomly in order to recognize it as a fire condition.
Using TDSA signal processing, the detector ignores
regularly chopped blackbody sources (occurring in areas
where moving conveyors and hot objects in proximity
to one another result in a regularly chopped IR signal),
because it looks for a less uniform signal. However, in the
presence of a regularly chopped signal, the detector may
be more susceptible to false alarms due to sporadic IR
that functions as a trigger when occurring in conjunction
with the regularly chopped signal.
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41. 1
Quick Fire (High Speed)
The Quick Fire (High Speed) feature can be used in
conjunction with the TDSA signal processing method.
This method overrides TDSA requirements in the event
of a sudden and intense signal, such as the result of a
flash fire. When Quick Fire is activated, the detector is
capable of responding to an intense fire signal in less
than 30 milliseconds (0.030 seconds). Using the Quick
Fire feature in conjunction with TDSA signal processing
allows the detector to provide a high speed response to
a large, non-flickering fire (such as in high pressure gas
applications). Additionally, when the Quick Fire feature
and TDSA signal processing are used in conjunction, the
detector maintains an ability to respond to fires that start
very small and grow in size and intensity over time.
UV DETECTOR OPTIONS
The UV detector output (measured in counts per second)
is compared to the fire threshold (the “sensitivity” setting).
If the radiant energy level from the fire exceeds the
selected alarm threshold level, the UV fire alarm output is
activated. In every application, it is crucial to ensure that
the radiant ultraviolet energy level from the expected fire
at the required distance from the detector will exceed the
selected sensitivity level.
The UV detector in the X5202 can be programmed for:
– Arc Rejection
– Standard Signal Processing
Arc Rejection
The Arc Rejection mode enables the detector to
prevent nuisance fire alarms caused by UV from short-
duration electrical arcs or electrostatic discharge, while
maintaining the ability to reliably detect the UV radiation
given off by a flame. Typical applications that benefit from
arc rejection logic include uncontrolled environments
where transient UV sources can be present, such as
many typical outdoor applications. Most false alarm
sources have short transient UV signatures, while fire
creates a long UV signature over many seconds. Most
fires are detected in a few seconds (see response times
in Appendix A).
Standard Signal Processing
Standard signal processing is recommended for high-
speed suppression systems only. To allow for high-speed
operation, the standard processing mode does not
incorporate the arc rejection programming. This mode
should only be used in a controlled, indoor environment or
in applications where the need for high speed detection
outweighs the need for resistance against unwarranted
UV alarms.
GENERAL APPLICATION
INFORMATION
RESPONSE CHARACTERISTICS
Response is dependent on the detector's sensitivity
setting, arc rejection, and time delay settings. Other
factors include distance, type of fuel, temperature of the
fuel, and time required for the fire to come to equilibrium.
As with all fire tests, results must be interpreted according
to an individual application.
See Appendix A for third-party approved fire test results.
Additional fire test results are available from Det-Tronics.
Welding
Electric arc welding is a source of intense ultraviolet
radiation. UV radiation from arc welding readily scatters
and can deflect across significant distances, even when
direct obstructions exist. Any open door or window can
allow nuisance UV radiation from arc welding to enter an
enclosed area, causing a possible response from the UV
detector.
It is recommended that the system be inhibited during
welding operations in situations where the possibility of a
false alarm cannot be tolerated. Gas welding mandates
system inhibit, since the gas torch is an actual fire. Arc
welding rods can contain organic binder materials in
the flux that burn during the welding operation and are
detectable by the detector. Welding rods with clay binders
do not burn and will not be detected by the detector.
However, system inhibit is always recommended, since
the material being welded may be contaminated with
organic substances (paint, oil, etc.) that will burn and
possibly cause the detector to alarm.
Articial Lighting
The detector should not be located within 5 feet (1.5 m)
of artificial lights. Excess heating of the detector could
occur due to heat radiating from the lights.
EMI/RFI Interference
The
detector
is resistant to interference by EMI and RFI,
and is EMC Directive compliant and CE marked. It will
not respond to a 5 watt walkie-talkie at distances greater
than 1 foot (0.3 m).
5
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1. 1
FALSE ALARM SOURCES
UV: The UV sensor is solar blind to the ultraviolet
component of solar radiation. However, it may
respond to sources of UV besides fire, such as arc
flash, electric arc welding, grinding metal, lightning,
high voltage corona, x-rays, and gamma radiation.
NOTE
Radiation generated by false alarm sources such
as periodic lightning or sparks in the area may be
effectively ignored by the detector using the arc
rejection feature or time delay.
IR: The detector has been designed to ignore steady
state infrared sources that do not have a flicker
frequency characteristic of a fire, however, it
should be noted that if these steady state infrared
sources are hot enough to emit adequate amounts
of infrared radiation in the response range of the
IR sensor and if this radiation becomes interrupted
from the view of the detector in a pattern
characteristic of a flickering flame, the IR sensor
can respond.
Any object having a temperature greater than
0° Kelvin (–273°C) emits infrared radiation. The
hotter the object, the greater the intensity of the
emitted radiation. The closer the infrared source is
to the detector, the greater the potential for a false
alarm. The IR sensor can respond to IR radiation
sources that can meet the amplitude and flicker
requirements of the detector such as vibrating hot
objects.
Although the detector is designed to reduce
false actuations, certain combinations of ambient
radiation must be avoided. For example, if IR
radiation with an intensity that exceeds the fire
threshold of the IR sensor should reach the detector
as a flickering signal, and if at the same time
an electric arc welding signal also reaches the
detector, an alarm output will be generated.
Sunlight: Infrared sensors that operate in the H2O
emission band can become sensitized by
modulated sunlight under certain conditions. As
an option, a sun shield may be installed. See the
Accessories section of this instruction manual for
ordering information.
FACTORS INHIBITING DETECTOR RESPONSE
Windows
Glass and Plexiglas windows significantly attenuate
radiation and must not be located between the detector
and a potential flame source. If the window cannot be
eliminated or the detector location changed, contact
Det-Tronics
for recommendations regarding window
materials that will not attenuate radiation.
Obstructions
Radiation must be able to reach the detector in order
for it to respond. Care must be taken to keep physical
obstructions out of the line of view of the detector. In
addition, UV or IR absorbing gases or vapors must not
be allowed to accumulate between the detector and
the protected hazard. See Table 3 for a list of these
substances.
Smoke
Smoke will absorb radiation. If accumulations of dense
smoke can be expected to precede the presence of a flame,
then detectors that are used in enclosed areas should be
mounted on the wall approximately 3 feet (0.9 m) from the
ceiling where the accumulation of smoke is reduced.
Detector Viewing Windows
It is important to keep the detector viewing windows as
free of contaminants as possible in order to maintain
maximum sensitivity. Commonly encountered substances
that can significantly attenuate UV and/or IR radiation
include, but are certainly not limited to, the following:
– Silicones
– Oils and greases
– Dust and dirt buildup
– Paint overspray
– Water and ice
95-8788
61. 1
IMPORTANT SAFETY NOTES
WARNING
Do not open the detector assembly in a hazardous
area when power is applied.The detector contains
limited serviceable components and should never
be opened. Doing so could disturb critical optical
alignment and calibration parameters, possibly
causing serious damage.
CAUTION
The wiring procedures in this manual are intended
to ensure proper functioning of the device under
normal conditions. However, because of the
many variations in wiring codes and regulations,
total compliance to these ordinances cannot be
guaranteed. Be certain that all wiring complies
with the NEC as well as all local ordinances. If in
doubt, consult the authority having jurisdiction
before wiring the system. Installation must be done
by a properly trained person.
CAUTION
To prevent unwanted actuation or alarm,
extinguishing devices must be disabled prior to
performing detection system tests or maintenance.
CAUTION
The UVIR flame detectors are to be installed in
places where the risk of mechanical damage is low.
ATTENTION
Remove the protective cover from the front of the
detector before activating the system.
ATTENTION
Observe precautions for handling electrostatic
sensitive devices.
The following is a partial list of compounds that exhibit
signicant UV absorption characteristics. These are
also usually hazardous vapors. While generally of little
consequence in small amounts, these gases can restrict
UV detection if they are in the atmosphere in heavy
concentrations. It should also be determined whether or
not large amounts of these gases may be released as a
result of a re-causing occurrence.
Acetaldehyde Methyl Methacrylate
Acetone Alpha-Methylstyrene
Acrylonitrile Naphthalene
Ethyl Acrylate Nitroethane
Methyl Acrylate Nitrobenzene
Ethanol Nitromethane
Ammonia 1-Nitropropane
Aniline 2-Nitropropane
Benzene 2-Pentanone
1,3 Butadiene Phenol
2—Butanone Pyridine
Butylamine Hydrogen Sulde
Chlorobenzene Styrene
1-Chloro-1-Nitropropane Tetrachloroethylene
Chloroprene Toluene
Cumene Trichloroethylene
Cyclopentadiene Vinyl Toluene
O-Dichlorobenzene Xylene
P-Dichlorobenzene
If UV-absorbing gases may be a factor in a given
application, precautionary measures should be taken.
Detectors can be placed closer to the potential hazard
area, and/or the sensitivity of the detection system can be
increased. Contact the factory for further details.
Substances such as methane, propane, butane, hexane,
camphor, and octane are not UV absorbing.
Absorption of infrared radiation in the range of 4.2 to 4.7
microns is not a signicant problem with most organic
vapors, with the exception of those compounds that
have triple bonds such as acetylene, nitriles, silane, or
isocyanates. Carbon dioxide concentrations higher than
normally present in the atmosphere can also cause
substantial loss of re detection sensitivity.
Table 3—UV and IR Absorbing Gases and Vapors
7
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1. 1
INSTALLATION
NOTE
The recommended lubricant for threads and O-rings
is a silicone-free grease (p/n 005003-001) available
from Detector Electronics. Under no circumstances
should a lubricant containing silicone be used.
DETECTOR POSITIONING
Detectors should be positioned to provide the best
unobstructed view of the area to be protected. The
following factors should also be taken into consideration:
• Identify all high risk fire ignition sources.
• Be sure that enough detectors are used to adequately
cover the hazardous area.
• Be sure that the unit is easily accessible for cleaning
and other periodic servicing.
• Verify that all detectors in the system are properly
located and positioned so that any fire hazards are
within both the Field of View (FOV) and detection
range of the detector. The Q1201C Laser Aimer
is recommended for establishing the detector's
FOV. Refer to Appendix A for specific information
regarding detector range and FOV.
• The detector should be aimed downward at least 10
to 20 degrees to allow lens openings to drain (see
Figure 1). The detector should be positioned so
that its FOV does not cover areas outside the area
that requires ame detection monitoring. This will
minimize the possibility of false alarms caused by
activities outside the area requiring protection.
• The detector must be mounted on a rigid surface in
a low vibration area.
• Dense fog, rain as well as certain gases and vapors
(see Table 3) can absorb UV and IR radiation and
reduce the sensitivity of the detector.
• If possible, fire tests can be conducted to verify
correct detector positioning and coverage.
• For ATEX/IECEx installations, the detector housing
must be electrically connected to earth ground.
DETECTOR ORIENTATION
Refer to Figure 2 and ensure that the
oi
reflector plate
will be oriented as shown when the
detector
is installed
and sighted. This will ensure proper operation of the
oi
system and will also minimize the accumulation of
moisture and contaminants between the
oi
reflector
plate and the viewing windows.
IMPORTANT
If removed, the
oi
reector plate must be securely
tightened to ensure proper operation of the
oi
system (40 oz./inches [28.2 N .cm] recommended).
CENTER AXIS
OF DETECTOR
FIELD OF VIEW
CENTER AXIS
OF DETECTOR
FIELD OF VIEW
INCORRECT
CORRECT
NOTE: DETECTOR MUST ALWAYS BE AIMED
DOWNWARD AT LEAST 10 TO 20 DEGREES.
D1974
Figure 1—Detector Orientation Relative to Horizon
IR VIEWING WINDOW
UV VIEWING WINDOW
DETECTOR STATUS INDICATOR
oiREFLECTOR PLATE
PLACE MAGNET
HERE TO INITIATE
MAGNETIC oi
oiMAGNET
B2134
Figure 2—Front View of the Detector
95-8788
81. 1
PROTECTION AGAINST MOISTURE DAMAGE
It is important to take proper precautions during
installation to ensure that moisture will not come in
contact with the electrical connections or components
of the system. The integrity of the system regarding
moisture protection must be maintained for proper
operation and is the responsibility of the installer. Verify
all covers are securely tightened upon installation.
If conduit is used, we recommend installing drains,
according to local codes, at water collection points
to automatically drain accumulated moisture. It is
also recommended to install at least one breather,
according to local codes, at upper locations to provide
ventilation and allow water vapor to escape.
Conduit raceways should be inclined so that water will
flow to low points for drainage and will not collect inside
enclosures or on conduit seals. If this is not possible, install
conduit drains above the seals to prevent the collection
of water or install a drain loop below the detector with a
conduit drain at the lowest point of the loop.
Conduit seals are not required for compliance with
explosion-proof installation requirements, but are
highly recommended to prevent water ingress in
outdoor applications. Units with M25 threads must use
an IP66/IP67 washer to prevent water ingress.
WIRING PROCEDURE
Wire Size and Type
The system should be wired according to local
codes. The wire size selected should be based on the
number of detectors connected, the supply voltage
and the cable length. Typically 16 AWG or 2.5
mm
2
shielded cable is recommended. Wires should be
stripped 1/2 inch, 12 mm. A minimum input voltage
of 18 Vdc must be present at the
detector
.
NOTE
Refer to “Power Consumption” in the
“Specications”section of this manual.
The use of shielded cable is required to protect against
interference caused by EMI and RFI. When using cables
with shields, terminate the shields as shown in Figures 7
through 12 and Figure 15. Consult the factory if not using
shielded cable.
In applications where the wiring cable is installed in
conduit, the conduit must not be used for wiring to other
electrical equipment.
If disconnection of power is required, separate disconnect
capability must be provided.
WARNING
All entries must contain appropriately rated plugs
or fittings. It is required that each plug or fitting
be wrench-tightened to an appropriate installation
torque and meet the minimum thread engagement
requirements per the applicable local standards,
codes, and practices in order to retain the dened
ratings. PTFE sealant or equivalent should be used
on NPT threads.
IMPORTANT
Devices certied for hazardous locations shall be
installed in accordance with EN/IEC 60079-14 and
NEC 505.
CAUTION
Installation of the detector and wiring should be
performed only by qualified personnel.
13.1
(33.3)
10.6
(27.0)
4.0
(10.2)
4.0
(10.2)
3.0
(7.6)
3.0
(7.6)
4X ø0.42
(1.1)
F2069
NOTE: THIS ILLUSTRATION SHOWS THE
DETECTOR MOUNTED AT THE 10° MINIMUM.
THESE DIMENSIONS WILL CHANGE BASED
ON THE DETECTOR’S MOUNTING ANGLE.
Figure 3—Q9033 Mounting Arm without Collar Attachment Dimensions in Inches (cm)
(See Figure 1 for Correct Detector Orientation.)
9
95-8788
1. 1
Detector Installation
Install the mounting arm assembly on a rigid surface.
The ideal installation surface should be free of vibration
and suitable to receive 3/8 inch or M10 bolts with a length
of at least 1 inch (25 mm). The surface must also have
sufficient capacity to hold the detector and mounting arm
weights (See "Specifications" section). Refer to the Q9033
Mounting Arm manual, number 95-8686, for additional
installation information. See Figure 3 for dimensions.
Relay and 0–20 mA Output Models
Follow the instructions below to install the X5202.
1. Make field connections following local ordinances
and guidelines in this manual. Refer to Figures 4
through 12.
2. Check all field wiring to be sure that the proper
connections have been made.
3. Replace and securely tighten all covers before
applying input power.
IMPORTANT
Do not test any wiring connected to the detector
with a meg-ohmmeter. Disconnect wiring at
the detector before checking system wiring for
continuity.
4. Make the final sighting adjustments and use a 14 mm
hex wrench to ensure that the mounting arm assembly
is tight.
EOL Resistors (Not Used with EQP Model)
To ensure that the insulating material of the wiring
terminal block will not be affected by the heat generated
by EOL resistors, observe the following guidelines when
installing the resistors.
1. Required EOL resistor power rating must be 5 watts
minimum.
NOTE
EOL resistors must be ceramic, wirewound
type, rated 5 watts minimum, with actual power
dissipation not to exceed 2.5 watts. This applies to
ATEX/IECEx installations only.
2. Resistor leads should be cut to a length of
approximately 1 1/2 inches, 40 mm.
3. Bend the leads and install the EOL resistor as shown
in Figure 6.
4. Maintain a 3/8 inch, 10 mm minimum gap between
the resistor body and the terminal block or any other
neighboring parts.
NOTE
The EOL resistor can only be used within the
ameproof terminal compartment. Unused conduit
entries shall be closed with suitable blanking
elements.
Figure 4—Detector Terminal Block
3/8 INCH (10 MM) GAP MINIMUM
1112
13
141516171819
B2126
BULKHEAD
Figure 6—EOL Resistor Installation
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
mA + mA –
mA + REF mA – REF
COM FIRE COM FIRE
NO FIRE NO FIRE
NC FIRE NC FIRE
COM FAULT COM FAULT
NO FAULT NO FAULT
+Vin +Vin
–Vin –Vin
–Vin
29
28
27
26
25
24
23
22
21
SPARE
SPARE
COM AUX
NO AUX
NC AUX
RS485 A
RS485 B
MAN Oi
E2061
Figure 5—Wiring Terminal Identication
95-8788
101. 1
C2136
FIRE ALARM PANEL
DETECTOR
ALARM
24 VDC
+
–
EOL
DEVICE 4
oi TEST 3
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
COM FIRE 2
COM FIRE
NO FIRE 2
NO FIRE
NC FIRE 2
NC FIRE
COM FAULT 1
COM FAULT
NO FAULT 1
N.O. FAULT
+Vin
–Vin
+Vin
–Vin –Vin
29
28
27
26
25
24
23
22
21
SPARE
SPARE
RS485 A
RS485 B
MAN Oi
mA + mA –
mA + REF mA – REF
COM AUX
NO AUX
NC AUX
SHIELD
WIRING NOTES:
1 IN NORMAL OPERATION WITH NO FAULTS OCCURRING, THE FAULT RELAY COIL IS ENERGIZED AND
THE NORMALLY OPEN (NO) AND COMMON (COM) CONTACTS ARE CLOSED.
2 ALARM RELAY IS NORMALLY DE-ENERGIZED WITH NO ALARM CONDITION PRESENT.
3 INDIVIDUAL MANUAL oiTEST SWITCHES CAN BE INSTALLED REMOTELY OR A DETECTOR SELECTOR AND
ACTIVATION SWITCH CAN BE INSTALLED AT THE FIRE PANEL. TEST SWITCHES ARE NOT SUPPLIED.
4 REFER TO SPECIFICATIONS SECTION FOR EOL RESISTOR VALUES. REFER TO EOL RESISTORS SECTION
FOR INSTALLATION DETAILS.
5 PROPERLY CERTIFIED HAZARDOUS LOCATION METALLIC CABLE GLANDS OR STOP PLUGS ARE
REQUIRED TO FILL ALL CONDUIT ENTRIES.
6 SHIELD MUST BE CONNECTED TO THE METALLIC CABLE GLAND. MAKE CERTAIN THAT THE INSULATION
IS REMOVED TO ENSURE ELECTRICAL CONNECTION BETWEEN THE SHIELD AND THE HOUSING.
Figure 7—Ex d Wiring Option
C2137
FIRE ALARM PANEL
DETECTOR
ALARM
ALARM
24 VDC
+
–
EOL
DEVICE 4
oi TEST 3
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
COM FIRE 2
COM FIRE
NO FIRE 2
NO FIRE
NC FIRE 2
NC FIRE
COM FAULT 1
COM FAULT
NO FAULT 1NO FAULT
+Vin
–Vin –Vin
+Vin
–Vin
29
28
27
26
25
24
23
22
21
SPARE
SPARE
RS485 A
RS485 B
MAN Oi
mA + mA –
mA + REF
mA – REF
COM AUX
NO AUX
NC AUX
WIRING NOTES:
1 IN NORMAL OPERATION WITH NO FAULTS OCCURRING, THE FAULT RELAY COIL IS ENERGIZED AND
THE NORMALLY OPEN (NO) AND COMMON (COM) CONTACTS ARE CLOSED.
2 ALARM RELAY IS NORMALLY DE-ENERGIZED WITH NO ALARM CONDITION PRESENT.
3 INDIVIDUAL MANUAL oiTEST SWITCHES CAN BE INSTALLED REMOTELY OR A DETECTOR SELECTOR AND
ACTIVATION SWITCH CAN BE INSTALLED AT THE FIRE PANEL. TEST SWITCHES ARE NOT SUPPLIED.
4 REFER TO SPECIFICATIONS SECTION FOR EOL RESISTOR VALUES. REFER TO EOL RESISTORS SECTION
FOR INSTALLATION DETAILS.
5 PROPERLY CERTIFIED HAZARDOUS LOCATION METALLIC CABLE GLANDS OR STOP PLUGS ARE
REQUIRED TO FILL ALL CONDUIT ENTRIES.
6 SHIELD MUST BE CONNECTED TO THE METALLIC CABLE GLAND. MAKE CERTAIN THAT THE INSULATION
IS REMOVED TO ENSURE ELECTRICAL CONNECTION BETWEEN THE SHIELD AND THE HOUSING.
SHIELD
Figure 8—Ex e Wiring Option
11
95-8788
1. 1
24 VDC
mA
PLC
–
+
600 Ω MAX
AT 24 VDC
–
+
D2138
oi TEST 1
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
mA +
mA + REF
mA –
–Vin –Vin
+Vin
29
28
27
26
25
24
23
22
21
MAN Oi
DETECTOR
Figure 9—Detector Wired for Non-Isolated 0 to 20 mA Current Output
(Sourcing)
24 VDC
mA
PLC
–
+
600 Ω MAX
AT 24 VDC
–
+
D2139
oiTEST 1
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
mA + mA –
mA – REF
29
28
27
26
25
24
23
22
21
MAN Oi
DETECTOR
–Vin –Vin
+Vin
Figure 10—Detector Wired for Non-Isolated 0 to 20 mA Current Output
(Sinking)
24 VDC
mA
PLC
–
+
600 Ω MAX
AT 24 VDC
–
+
D2140
oi TEST 1
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
mA + mA – 29
28
27
26
25
24
23
22
21
MAN Oi
DETECTOR
–+
24 VDC
–Vin –Vin
+Vin
Figure 11—Detector Wired for Isolated 0 to 20 mA
Current Output (Sourcing)
24 VDC
mA
PLC
–
+
600 Ω MAX
AT 24 VDC
–
+
D2141
oiTEST 1
9
8
7
6
5
4
3
2
1
19
18
17
16
15
14
13
12
11
mA + mA – 29
28
27
26
25
24
23
22
21
MAN Oi
DETECTOR
–
+
24 VDC
–Vin –Vin
+Vin
Figure 12—Detector Wired for Isolated 0 to 20 mA
Current Output (Sinking)
NOTES: 1. INDIVIDUAL MANUAL oiTEST SWITCHES CAN BE
INSTALLED REMOTELY OR A DETECTOR SELECTOR AND
ACTIVATION SWITCH CAN BE INSTALLED AT THE FIRE
PANEL. TEST SWITCHES ARE NOT SUPPLIED.
95-8788
121. 1
EQP Model
1. Connect external wires to the appropriate terminals
inside the terminal compartment, shown in Figure 13.
See Figure 14 for terminal identification.
2. Connect the shield of the power cable to earth
ground at the power source.
3. Connect shields for the LON cable as indicated. See
Figure 15.
NOTE
DO NOT ground any shields at the detector
housing.
4. With input power disconnected, set the device
network address. (See the “Setting Device Network
Addresses” section of this manual for switch setting
procedure.)
5. Check all field wiring to be sure that the proper
connections have been made.
6. Replace and securely tighten all covers before
applying input power.
7. Make the final sighting adjustments and use a 14 mm
hex wrench to ensure that the mounting arm assembly
is tight.
NOTE
Refer to the Eagle Quantum Premier system
manual, number 95-8533, for information regarding
power requirements, network communication
cable requirements, and conguration.
Figure 14—Wiring Terminal Identication for EQP Model
Figure 13—Detector Terminal Block (EQP Model)
6
5
4
3
2
1
16
15
14
13
12
11
SHIELD SHIELD
COM 1 A COM 2 A
COM 1 B COM 2 B
PWR SHIELD PWR SHIELD
+Vin +Vin
–Vin –Vin
C2089
13
95-8788
1. 1
Figure 15—A Typical EQP System
EQP2100PSM
SHIELD
4 9
24 VDC –
6 7
24 VDC +
5 8
B
11 3
A
10 2
B 2
3
4
C 1
SHIELD
12 1
COM2 COM1
BUS BAR P3
AC LINE
N
H
Detector (EQP Model)
SHIELD
13 3
24 VDC –
11 1
24 VDC +
12 2
B
14 4
A
15 5
SHIELD
16 6
COM2 COM1
Detector (EQP Model)
SHIELD
13 3
24 VDC –
11 1
24 VDC +
12 2
B
14 4
A
15 5
SHIELD
16 6
COM2 COM1
Detector (EQP Model)
SHIELD
13 3
24 VDC –
11 1
24 VDC +
12 2
B
14 4
A
15 5
SHIELD
16 6
COM2 COM1
Detector (EQP Model)
SHIELD
13 3
24 VDC –
11 1
24 VDC +
12 2
B
14 4
A
15 5
SHIELD
16 6
COM2 COM1
EQP3700DCIO
SHIELD
6 3
24 VDC –
5 2
24 VDC +
4 1
B
5 2
A
4 1
SHIELD
6 3
COM2 COM1
P1
P2
P3P4
IN–/OUT+
B B
COMMON
C C
+ SUPPLY
A A
CH 1
CH 5
IN–/OUT+
B B
COMMON
C C
+ SUPPLY
A A
CH 2
CH 6
IN–/OUT+
B B
COMMON
C C
+ SUPPLY
A A
CH 3
CH 7
IN–/OUT+
B B
COMMON
C C
+ SUPPLY
A A
CH 4
CH 8
CONTROLLER
24 VDC –
4 2
24 VDC +
3 1
B
52 49
A
53 50
TxD A
59 56
RxD B
58 55
GND GND
57 54
SHIELD
51 48
COM2 COM1
P1
P7
P9 P8
P4 P5
1+ 5+
5 13
1– 5–
6 14
2+ 6+
7 15
2– 6–
8 16
3+ 7+
9 17
3– 7–
10 18
4+ 8+
11 19
4– 8–
12 20
P2 P3
C45
NO 46
NC 47
P6
FAULT
GND 5
RXD 2
TXD 3
DB-9
CONNECTION
TO COM PORT
OF PC
DIGITAL INPUTS
C C
21 33
NO NO
22 34
NC NC
23 35
RELAY 1
RELAY 5
C C
24 36
NO NO
25 37
NC NC
26 38
RELAY 2
RELAY 6
C C
27 39
NO NO
28 40
NC NC
29 41
RELAY 3
RELAY 7
C C
30 42
NO NO
31 43
NC NC
32 44
RELAY 4
RELAY 8
24 VDC
SUPPLY
+ –
24 VDC
BATTERY
+ –
H N
AC LINE
POWER
DISTRIBUTION
+
+
++
+
++
–
–––
–
–
–
A2208
95-8788
141. 1
SETTING DEVICE NETWORK ADDRESSES
(EQ and EQP Models Only)
Overview of Network Addresses
Each device on the LON must be assigned a unique
address. Addresses 1 to 4 are reserved for the
controller. Valid addresses for field devices are from
5 to 250.
IMPORTANT
If the address is set to zero or an address above
250, the switch setting will be ignored.
Duplicated addresses are not automatically detected.
Modules given the same address will use the number
given and report to the controller using that address.
The status word will show the latest update, which
could be from any of the reporting modules using that
address.
Setting Field Device Addresses
Selection of the node address is done by setting rocker
switches on an 8 switch “DIP Switch Assembly” within
the detector’s housing. Refer to Figure 16 for switch
location.
WARNING
The network address switches are located within
the detector housing. Removal of the sensor
module (the "front" half of the detector) which
contains powered electrical circuits is required to
gain access to the network address switches. For
hazardous areas, the area must be de-classified
before attempting disassembly of the device.
Always observe precautions for handling
electrostatic sensitive devices.
The address number is binary encoded with each switch
having a specific binary value with switch 1 being the
LSB (Least Significant Bit), see Figure 17. The device’s
LON address is equal to the added value of all closed
rocker switches. All “Open” switches are ignored.
Example: for node No. 5, close rocker switches 1 and
3 (binary values 1 + 4); for node No. 25, close rocker
switches 1, 4, and 5 (binary values 1 + 8 + 16).
NOTE
The eld device sets the LON address only when
power is applied to the device. Therefore, it is
important to set the switches before applying
power. If an address is ever changed, system
power must be cycled before the new address will
take effect.
After setting address switches, record the address
number and device type.
ADDRESS SWITCHES SENSOR MODULE
REMOVED FROM HOUSING
A2191
Figure 16—Location of Address Switches
1 2 3 4 5 6 7 8
1 2 4 8 16 32 64 128
ON
NODE ADDRESS EQUALS THE ADDED VALUE
OF ALL CLOSED ROCKER SWITCHES
A2190
BINARY
VALUE
CLOSED = ON
OPEN = OFF
Figure 17—Address Switches for Detector
15
95-8788
1. 1
STARTUP PROCEDURE
When installation of the equipment is complete, perform
the “Fire Alarm Test” below.
FIRE ALARM TEST
1. Disable any extinguishing equipment that is
connected to the system.
2. Apply input power to the system.
3. Initiate an
oi
test. (See “Magnetic
oi
/ Manual
oi
”
under Optical Integrity in the "Description" section of
this manual.)
4. Repeat this test for all detectors in the system. If a unit
fails the test, refer to the “Troubleshooting” section.
5. Verify that all detectors in the system are properly
aimed at the area to be protected. (The Q1201C
Laser Aimer is recommended for this purpose.)
6. Enable extinguishing equipment when the test is
complete and the detectors have returned to normal
operation.
TROUBLESHOOTING
1. Disable any extinguishing equipment that is
connected to the unit.
2. Inspect the viewing windows for contamination and
clean as necessary. (Refer to the “Maintenance”
section for complete information regarding cleaning
of the detector viewing windows.)
3. Check input power to the unit.
4. If the fire system has a logging function, check the
fire panel log for output status information. See Table
4 for information regarding 0 to 20 mA output.
5. The use of the Enhanced Flame Inspector cable
and software from Det-Tronics can be considered to
determine the nature of the fault condition. Refer to
instruction manual 95-8751 for more information.
6. Turn off the input power to the detector and check all
wiring for continuity. Important: Disconnect wiring
at the detector before checking system wiring for
continuity.
7. If all wiring checks out and cleaning of the
oi
reflector plate/window did not correct the fault
condition, check for high levels of background UV or
IR radiation by covering the detector with the factory
supplied cover or aluminum foil. If the fault condition
clears, extreme background UV or IR radiation is
present. Re-adjust the view of the detector away from
the UV or IR source or relocate the detector.
8. Remove the factory supplied cover or aluminum
foil from the detector and verify the detector has
returned to normal operation before enabling any
extinguishing equipment connected to the unit.
If none of these actions corrects the problem, please
contact your local Det-Tronics Representative or
alternatively you may contact Det-Tronics Technical
Support by calling 1-800-765-3473 to obtain assistance.
NOTE
It is highly recommended that a complete spare
be kept on hand for field replacement to ensure
continuous protection.
Table 4—Current Level Output Troubleshooting Guide
1If fault continues, return device to factory for repair.
2See “Maintenance” section for cleaning procedure.
Current Level
(±0.3 mA) Status Action
0 mA Power Fault Check system wiring.
1 mA General Fault Cycle power.1
2 mA
oi
Fault Clean windows.2
4 mA Normal Operation
8 mA Hi Background IR
(IR pre-alarm)
Remove IR source or
aim detector away
from IR source.
12 mA Hi Background UV
(UV alarm)
Remove UV source
or aim detector away
from UV source.
14 mA Hi Background IR
(IR alarm)
Remove IR source or
aim detector away
from IR source.
16 mA
UV and IR sensors
in pre-alarm, or one
in alarm and the
other in pre-alarm.
If no fire exists, remove
UV and IR sources
or aim detector away
from sources.
20 mA Fire Alarm
95-8788
161. 1
MAINTENANCE
IMPORTANT
Periodic flamepath inspections are not
recommended, since the product is not intended
to be serviced and provides proper ingress
protection to eliminate potential deterioration of the
amepaths.
WARNING
To avoid a potential electrostatic discharge (ESD),
the painted surface of the detector should only be
cleaned with a damp cloth.
WARNING
The sensor module (“front” half of the detector)
contains no user serviceable components and
should never be tampered with.
To maintain maximum sensitivity and false alarm
resistance, the viewing windows of the detector must be
kept relatively clean. Refer to the following procedure for
cleaning instructions.
CLEANING PROCEDURE
CAUTION
Disable any extinguishing equipment that is
connected to the unit to prevent unwanted
actuation.
To clean the windows and
oi
reflector plate, use the
window cleaner (p/n 001680-001) with a soft cloth, cotton
swab, or tissue and refer to the following procedure:
1. Disable any extinguishing equipment that is
connected to the unit.
NOTE
Remove input power when cleaning the detector
windows. The rubbing motion on the surface of
the windows during cleaning can create static
electricity that could result in unwanted output
activation.
2. Clean the viewing windows and reflective surfaces
of the
oi
reflector plate using a clean cloth, cotton
swab, or tissue with the window cleaning solution.
Use Isopropyl alcohol for contaminations that the
window cleaning solution can not remove. If a fault
condition is still indicated after cleaning, remove and
clean the
oi
reflector plate using the
oi
reflector
plate Removal and Replacement procedure.
IMPORTANT
When used in extreme environments, the reflective
surface of the detector
oi
reflector plate may
eventually deteriorate, resulting in reoccurring
oi
faults
and the need for
oi
reector plate replacement.
oiREFLECTOR PLATE REMOVAL AND
REPLACEMENT
1. Disable any extinguishing equipment that is
connected to the unit.
2. Loosen the two captive screws, then grasp the
oi
reflector plate by the visor and remove it from the
detector. See Figure 18.
3. Install the new (or cleaned)
oi
reflector
plate.
4. Recalibrate the detector's
oi
system. Refer to the
Inspector Monitor manual (95-8581) for instructions
regarding
oi
reflector plate replacement and
oi
system recalibration.
CAUTION
Do not replace the
oi
reector plate without also
recalibrating the
oi
system.
Recalibration of the
oi
system requires the use of the
Inspector Connector Cable and Inspector Monitor
Software. These two items are included in the
oi
replacement kit, or they can be purchased separately.
See the "Ordering Information" section for details.
LOOSEN TWO CAPTIVE SCREWS
GRASP VISOR AND
REMOVE oiREFLECTOR PLATE
C2135
Figure 18—oiReector Plate Removal
17
95-8788
1. 1
CLOCK BATTERY
The real time clock has a backup battery that will
operate the clock with no external power. Return the
device to the factory for battery replacement if needed.
NOTE
If the backup battery is depleted, there is no effect
on the operation of the ame detector, but the time
stamping of the data log may be affected.
FEATURES
• Responds to a fire in the presence of modulated
blackbody radiation (i.e., heaters, ovens, turbines)
without false alarm
• High speed capability
• Built-in data logging / event monitoring, up to 1500
events (up to 1000 general, 500 alarms)
• Heated optics of IR channel for increased resistance
to moisture and ice
• Automatic, manual, or magnetic
oi
testing
• Easily replaceable
oi
reflector plate
• Fire, fault, and auxiliary relays standard
• 0 to 20 mA isolated output (optional)
• Eagle Quantum Premier LON/SLC output (optional)
• HART communication (optional)
• FDT/DTM capable
• A tri-color LED on the detector faceplate indicates
normal condition and notifies personnel of fire alarm
or fault conditions
• Operates under adverse weather conditions
• Mounting arm allows easy sighting
• Integral wiring compartment for ease of installation
• Explosion-proof/flame-proof detector housing. Meets
FM certification requirements.
• Class A wiring per NFPA-72
• Spectral Sensitivity Range: X5202 IR wavelength
range 2-3 microns, UV wavelength range 185-265
nanometers
• 3 year warranty
• Advanced signal processing (ARC/TDSA)
Associated Manuals
List of related manuals:
TITLE FORM NUMBER
HART Addendum
95-8636
Q9033 Mounting Arm
and Collar Attachment 95-8686
Enhanced Flame Inspector
Software for X-Series Flame
Detectors
95-8751
95-8788
181. 1
SPECIFICATIONS
OPERATING VOLTAGE—
24 Vdc nominal (18 Vdc minimum, 30 Vdc maximum).
Maximum ripple is 2 volts peak-to-peak.
POWER CONSUMPTION—
Without heater: 2.8 watts at 24 Vdc nominal;
4.8 watts at 24 Vdc in alarm.
3.1 watts at 30 Vdc nominal;
5.4 watts at 30 Vdc in alarm.
Heater only: 8 watts maximum.
Total power: 17.5 watts at 30 Vdc with EOL resistor
installed and heater on maximum.
EOL resistor must be ceramic, wirewound type, rated
5 watts minimum, with actual power dissipation not to
exceed 2.5 watts.
For HART models, refer to Addendum number 95-8636.
POWER UP TIME—
Fault indication clears after 0.5 second; device is ready
to indicate an alarm condition after 30 seconds.
OUTPUT RELAYS—
Fire Alarm relay, Form C, 5 amperes at 30 Vdc:
The Fire Alarm relay has redundant terminals
and normally open / normally closed contacts,
normally de-energized operation, and latching or
non-latching operation.
Fault relay, Form A, 5 amperes at 30 Vdc:
The Fault relay has redundant terminals and
normally open contacts, normally energized
operation, and latching or non-latching operation.
Auxiliary relay, Form C, 5 amperes at 30 Vdc:
The auxiliary relay has normally open / normally
closed contacts, normally energized or
de-energized operation, and latching or non-
latching operation.
CURRENT OUTPUT (Optional)—
0 to 20 milliampere (±0.3 mA) dc current, with a
maximum loop resistance of 500 ohms from 18 to
19.9 Vdc and 600 ohms from 20 to 30 Vdc.
LON OUTPUT—
Digital communication, transformer isolated (78.5 kbps).
TEMPERATURE RANGE—
Operating: –40°F to +167°F (–40°C to +75°C).
Storage: –67°F to +185°F (–55°C to +85°C).
Hazardous location ratings from –55°C to +75°C available
on flameproof model.
HUMIDITY RANGE—
0 to 95% relative humidity, can withstand 100%
condensing humidity for short periods of time.
0°
15°
30°
45°
15°
30°
45°
VIEWING ANGLE
C1288
80 (24)
70 (21)
60 (18)
50 (15)
40 (12)
30 (9)
20 (6)
10 (3)
Figure 19—Field of View at Indicated Distance in Feet (m) for a 30 inch
Hydrogen Plume Fire at Very High UV and IR Sensitivity
10.2
(25.9)
4.8
(12.2)
4.7
(11.9)
B2223
Figure 20—Dimensions in Inches (cm)
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