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The structure of the photoelectric hybrid cable is to cover 250 um optical fiber into the loose tube of the high modulus material. The core of the cable core is a FRP or metal core (some structures need to add a layer of PE cushion layer). The electric wire and the loose tube (and the filling rope) surround the center to strengthen the core to synthesize the compact and circular cable core. Double coated strip (PSP) longitudinal package after extruded polyethylene or low smoke halogen (LSZH) cable sheath.
·Have good flexibility and mechanical properties.
·Photoelectric integration, fully conserve pipeline resources
·The cable part and the optical cable part are relatively independent structure, which is convenient for the introduction, the lead out and the connection of the installation.
·Will power lines, telephone lines, TV lines, cable, monitoring line, data line and other network, save the cost
·Greater operating temperature range
·Greater construction temperature range
·Optical cable diameter and bending radius are small, in the next small space also can freely install compatible optical signal transmission and power transmission at the same time.
·Optimization of transmission line design, energy saving effect is significant
·One, the transmission of electrical energy in the transmission of information at the same time, and can detect the line working state
·Fiber composite in the wire, stop by ground lightning fiber broken, broken wire
·Will not be due to the role of the field strength caused by cable suffered electrical corrosion or damage caused by cable, broken fiber accident
·There is no hidden danger to the original route with additional line load.
·Telecom Network Construction
·Construction of communication base stations in rural and remote areas of cities and towns
·Urban residential communities and buildings in the optical fiber
·Security monitoring project
·And other occasions where information and power are needed.
·Product standards
·Light cable tensile, impact, bending, flattening, torsion, winding and wear in compliance with YD/T901-2001 requirements
|
G.652 |
G.655 |
50/125μm |
62.5/125μm |
|
Max attenuation |
@850nm |
|
|
3.5dB/km |
3.5dB/km |
@1300nm |
|
|
1.5dB/km |
1.5dB/km |
|
@1310nm |
0.45dB/km |
0.45dB/km |
|
|
|
@1550nm |
0.30dB/km |
0.30dB/km |
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|
|
Typical attenuation |
@850 |
|
|
3.0dB/km |
3.0dB/km |
@1300 |
|
|
1.0dB/km |
1.0dB/km |
|
@1310nm |
0.40dB/km |
0.40dB/km |
|
|
|
@1550nm |
0.25dB/km |
0.25dB/km |
|
|
|
Mini bandwith |
@850 |
|
|
400MHZ·km |
160MHZ·km |
@1300 |
|
|
800MHZ·km |
500MHZ·km |
item |
|
technical requirement |
remark |
Allowable bending radius(mm) |
dynamic |
30D |
|
static state |
20D |
|
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Allowable pull(N) |
short-term |
3000 |
|
Long-term |
1500 |
|
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Allowable press force |
short-term |
3000 |
|
Long-term |
1000 |
|
|
Operating temperature range |
wire |
-15℃~+70℃ |
Meet GB5023-1997 |
Other materials other than |
-40℃~+70℃ |
|
|
Water resistance / waterproof performance |
Long term immersion in water without water seepage |
Except the conductor of the wire |
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No leakage |
|||
Construction temperature range |
-20℃~+60℃ |
In addition to electric wire |
|
-0℃~+60℃ |
wire |
||
weight |
374kg/km(RV-2*2.5mm) |
|
|
Mechanical properties |
The optical cable tensile, impact, bending, flattening, torsion, winding and wear in compliance with YD/T901-2001 requirements |
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Applicable laying mode |
Suitable for pipe, channel, cable trench, aerial, buried and other installation |
M
Martin |
German |
M
Mac Donald |
Dublin reland |
A
Alexander |
United Kingdom |
G
Gabin |
France |
W
William Dinh |
Canada |
A
Ahern |
United Kingdom |
A
Anthony Italy |
Italy |
S
Semele |
United States |
C
Carlos |
Brazil |
G
Ginette |
Spain |