Product Detail

   CITCABLE:  High Radiation Absorbed dose rate Optical Fibre Cable
  Characteristics: Suitable for use in harsh environments, up to 10Gbits/s, Tight and semi-loose cables, EASY TERMINATION
Temperature Range:  -196°C to +260°C  and short time 300°C     
 Applications
  • Aerospace
  • Atomic energy
  • Medical
  • Oil/gas
  • Scientific research
Characteristics
  • Low dispersion and low attenuation
  • Superior mechanical protection and excellent stripping performance
  • Outstanding uniformity and geometry control
  • Low radiation loss
$0.6 -$0.65 /Piece | 1000 Pieces (Min.Order)

Single-Mode Polyimide and PEEK
   Single-Mode (SM) fibers with polyimide primary and PEEK secondary coatings are specifically designed for use in harsh environments where bare fiber fails. The fibers target distributed sensing applications requiring chemical, abrasion, and radiation resistance. Excellent for the following applications: pipeline monitoring, structural monitoring, embedded sensor, flexible risers, geotechnical risk monitoring, fracking micro-seismic sensors, enhanced oil recovery (EOR), haptic feedback, and biomedical in vivo sensors.

SMFF(Single Mode Fluoride Fiber)
SMFF(Single Mode Fluoride Fiber)
MMFF(Multi Mode Fluoride Fiber)
DCFF(Double Cladding Fluoride Fiber)
CITCABLE radiation resistant sigle-mode fibres are developed by adjusting the composition of optical fibre and improving the process technology to meet the special application requirements of the fibre in the radiation environment. The optical properties are optimized at 1310nm and 1550nm oprerating wavelenghth. Low attenuation and low dispersion can be achieved.
                                                                                   CITCABLE     A      B      C 
According to Standard
TIA/EIA 455-64 (dB/100m)
1310 Total dose 50Krad
dose rate 0.1rad/s(25℃)
induced attenuation
-- ≤ 0.3 ≤ 0.3
1310, 1550 Total dose 2000Gy
dose rate 0.5Gy/s(25℃)
induced attenuation
≤ 0.9 ≤ 0.8 ≤ 0.8
1310, 1550 Total dose 200000Gy
dose rate 0.5Gy/s(25℃)
induced attenuation
≤ 2.5 ≤ 2.0 ≤ 2.0