Det-Tronics X9800 IR Flame Detector User Manual

95-8554

4

11.1

general application

information

REspONsE CHARACTERIsTICs
Response is dependent on the detector's sensitivity

setting, 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
It is recommended that the system be bypassed during

welding operations in situations where the possibility of a

false alarm cannot be tolerated. Gas welding mandates

system bypass, 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 X9800. Welding rods with clay binders

do not burn and will not be detected by the X9800.

However, system bypass is always recommended, since

the material being welded may be contaminated with

organic substances (paint, oil, etc.) that will burn and

possibly cause the X9800 to alarm.

Artificial Lighting
The X9800 should not be located within 3 feet (0.9 m)

of artificial lights. Excess heating of the detector could

occur due to heat radiating from the lights.

EMI/RFI Interference
The X9800 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).

Non-Carbon Fires
The response of the X9800 is limited to carbonaceous

fuels. It should not be used to detect fires from fuels

that do not contain carbon, such as hydrogen, sulfur and

burning metals.

FALsE ALARM sOuRCEs
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.