Transcript
Fiber Data Sheet Singlemodefiber (SM) Common fiber type standard fiber decribtion
E9
E9/125 Singlemode Fiber ITU-T G.652 D; EN188000, EN1888100, EN1888101; VDE 0888/part 102, VDE 0888/part 103, TS 0311/part 3 and TS 0311/part 2 of DTAG The fiber is ideally designed for use in metropolitan, local and access networks due to its superior specifications - low optical loss aross the entire wavelength range from 1260 to 1625 nm, tightest available geometry, low splice loss and low polarization mode dispersion.
Mechanical Properties core diameter d core concentricity error cladding diameter cladding non-circularity cladding/coating concentricity error coating non-circularity fiber diameter
at 1310 nm at 1550 nm
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level coating strip force bending radius Optical Properties attenuation
attenuation inequality (.......) attenuation (Makrobending) attenuation alteration (range -60 up to +85°C) attenuation for WDM/EÜS chromatic dispersion
at 1310 at 1383 at 1490 at 1550 at 1625 at 1310 at 1310 at 1310 at 1550 at 1285 at 1260 at 1480
nm nm nm nm nm and 1550 nm and 1550 nm and 1550 nm ±20 nm ÷ 1330 nm ÷ 1360 nm ÷ 1580 nm
polarization mode dipersion (PMD) PMD Link Design Value acc. IEC 60794/5.5 Method 1 fiber cut-off wavelength (referred to RTM) λcf-range
1
µm µm µm µm % µm % µm µm N kpsi N mm
max / typical ≤0.34 / ≤0.32 ≤0.31 / ≤0.28 ≤0.23 / ≤0.21 ≤0.21 / ≤0.19 ≤0.23 / ≤0.20 ≤0.05 ≤0.05 ≤0.05 ≤0.22 ≤3 ≤12 ≤19 ≤0.1 ≤0.06 1150÷1330
dB/km dB/km dB/km dB/km dB/km dB/km dB dB/km dB/km ps/(nm*km) ps/(nm*km) ps/(nm*km) ps/√km ps/√km nm
1260
nm
point defect at pulse-width 10ns zero dispersion wavelength
at 1310 and 1550 nm λ0
≤0.05 1300 ÷ 1322
dB nm
zero dispersion slope
s0
≤0.092
ps/(nm²*km)
refraction index
at 1310 nm at 1550 nm
1.467 1.468
cable cut-off wavelength
λcff-range
9.2 ±0.4 10.4 ±0.5 ≤0.5 125 ±0.7 0.7 ≤12.0 ≤6.0 242 ±5 250 ±10 ≥8 ≥120 ≤3.5 ≥30
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Fiber Data Sheet Singlemodefiber (SM) - Low Bend Sensitive
E9/125 Singlemode Fiber with higher Bend Performance ITU-T G.657 A1, A2/B2; IEC 60793-2-50 type B.1.3 The macrobending and microbending loss improvements of this low bend sensitive fiber offer a number of advantages for demanding access, enterprise and central office applications. The fiber enables more compact cabinet and enclosure designs and protects the network against excessive loss resulting from inadvertent fiber bends. It is less susceptible to physical disturbancees from cable flexing, pulling and crushing, as well as the intricate routing conditions within enclosures and cabinets. The optimized bend characteristics of this fiber also help improve cable performance in demanding high-stress and low-temperature environments by providing double the microbend protection of conventional singl-mode fibers.
Mechanical Properties core diameter d coreconcentricity error cladding diameter cladding non-circularity cladding/coating concentricity error coating non-circularity fiber diameter
at 1310 nm at 1550 nm
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level coating strip force bending radius Optical Properties attenuation
refraction index attenuation inequality (.......) attenuation alteration (range -60 up to +85°C) chromatic dispersion polarization mode dipersion (PMD) fiber cut-off wavelength (referred to RTM)
at 1310 nm at 1383 nm at 1490 nm at 1550 nm at 1625 nm at 1310 nm at 1550 nm at 1310 and 1550 nm at 1310 und 1550 nm at 1288 ÷1339 nm at 1550 nm λcf-range
A2/B2 8.5 - 9.3 9.5 - 10.5 ≤0.5 125 ±0.7 1.0 ≤12.0 ≤6.0 235 - 245 max. 265 ≥8 ≥100 ≤3.5 ≥10
max. / typical ≤0.35 / ≤0.34 ≤0.31 / ≤0.28 ≤0.24 / ≤0.21 ≤0.21 / ≤0.19 ≤0.24 / ≤0.20 1.467 1.468 ≤0.05 ≤0.05 ≤3.5 ≤18 ≤0.2 1150÷1330
max. / typical ≤0.35 / ≤0.34 ≤0.31 / ≤0.28 ≤0.24 / ≤0.21 ≤0.21 / ≤0.19 ≤0.24 / ≤0.20 1.467 1.468 ≤0.05 ≤0.05 ≤3.5 ≤18 ≤0.2 1150÷1330
µm µm µm µm % µm % µm µm N kpsi N mm
dB/km dB/km dB/km dB/km dB/km
dB/km dB/km ps/(nm*km) ps/(nm*km) ps/√km nm
1260
1260
nm
point defect at pulse-width 10ns zero dispersion wavelength
at 1310 and 1550 nm λ0
≤0.05 1302 ÷ 1322
≤0.05 1300 ÷ 1324
dB nm
zero dispersion slope
s0
≤0.092
≤0.092
ps/(nm²*km)
at 1550 nm at 1625 nm at 1550 nm at 1625 nm at 1550 nm at 1625 nm at 1550 nm at 1625 nm
≤0.01 ≤0.05 ≤0.2 ≤0.5 ≤0.2 ≤0.5 -
≤0.03 ≤0.1 ≤0.1 ≤0.2 ≤0.5 ≤1.0
dB dB dB dB dB dB dB dB
cable cut-off wavelength
Macrobend Performances 100 turns on a 25mm radius mandrel 10 turns on a 15mm radius mandrel 1 turns on a 10mm radius mandrel 1 turns on a 7.5mm radius mandrel
λcff-range
A1 8.5 - 9.3 9.5 - 10.5 ≤0.5 125 ±0.7 1.0 ≤12.0 ≤6.0 235 - 245 max. 265 ≥8 ≥100 ≤3.5 ≥10
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Fiber Optic Cables
Common fiber type standard fiber describtion
E9
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Fiber Data Sheet NZDF-Singlemodefiber (NZDF) Common fiber type standard fiber describtion
E8
Non-Zero-Dispersion-Shifted Singlemode Fiber ITU-T G.655, ITU-T G.656; EN188000, EN1888100, EN1888101 core consists of SiO2 doped with GeO2; optical cladding of quarzglass (SiO2); step profile of the refraction index, matched cladding, phosphorus free; protective coating consisting of two layers of UV-cured acrylate resins
Mechanical Characteristics
G.656 (G.655.c, e) True-Wave Reach 8.6 ±0.4 125 ±0.7 ≤0.5 ≤0.7 ≤12.0 ≤6.0 242 ±5 265 ≥8
G.655.d (G.655.c) True-Wave RS 8.4 ±0.6 8.7 ±0.6 125 ±0.7 ≤0.5 ≤0.7 ≤12.0 ≤6.0 242 ±5 265 ≥8
Tera Light MetroFiber 9.2 ±0.5 125 ±1 ≤0.6 ≤1.0 ≤12.0 ≤5.0 242 ±7 265 ≥8
Tera Light UltraFiber 9.2 ±0,5 125 ±1 ≤0.6 ≤1.0 ≤12.0 ≤6.0 242 ±7 265 ≥8
9.6 ±0.4 125 ±0.7 ≤0.5 ≤0.7 ≤12.0 ≤6.0 245 ±5 265 ≥8
µm µm µm µm % µm % µm µm N
100 ≤3.5 ≥30
≥100 ≤3.5 ≥30
≥100 ≤3 ≥30
≥100 ≤3.5 ≥30
≥100 ≤3 ≥30
kpsi N mm
at 1550 nm at 1625 nm at 1383 ±3 nm
≤0.22 ≤0.24 ≤0.4
≤0.22 ≤0.24 ≤0.4
≤0.25 ≤0.28 ≤1.0
≤0.22 ≤0.25 ≤0.7
≤0.22 ≤0.24 ≤0.4
dB/km dB/km dB/km
at 1550 nm at 1625 nm
≤0.5 ≤0.5
≤0.5 ≤0.5
≤0.5 ≤0.5
≤0.5 ≤0.5
≤0.5 ≤0.5
dB dB
at 1550 nm at 1625 nm
≤0.05 ≤0.05 ≤0.05
≤0.05 ≤0.05 ≤0.05
≤0.05 ≤0.05 ≤0.05
≤0.05 ≤0.05 ≤0.05
≤0.05 ≤0.05 ≤0.05
dB dB dB/km
at 1550 nm at 1530 ÷ 1565 nm at 1565 ÷ 1620 nm link design value max. individual fiber at 1550 nm at 1550 nm
≤0.05 5.5-8.9 6.9-11.4 ≤0.04 ≤0.1 ≤0.05 1.470
≤0.05 2.6-6.0 4.0-8.9 ≤0.04 ≤0.1 ≤0.05 1.470
≤0.05 5.5-10.0 7.5-13.8 ≤0.08 ≤0.2 ≤0.1 1.469
≤0.1 5.5-10.0 7.5-13.4 ≤0.04 ≤0.05 1.469
≤0.05 2.6-6.0 4.5-11.2 ≤0.04 0.1 ≤0.05 1.468
dB ps/(nm*km) ps/(nm*km) ps/√km ps/√km dB
®
core diameter d cladding diameter core/cladding excentricity cladding non-circularity cladding/coating excentricity coating non-circularity fiber diameter
at 1550 nm at 1600 nm
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level stripping force bending radius Optical Characteristics attenuation attenuation (water peak) attenuation (macrobending) 1 turn, Ø 32mm 100 turns, Ø 75mm1) attenuation alteration (range -60 up to +85°C) no point discontinuity chromatic dispersion polarisation modedispersion (PMD) point defect refraction index
1)
3
G.656 (G.655.e) ®
G.656 (G.655.e) TM
G.655.d TM
Leaf
®
at TeraLight Fibers: Ø 60 mm TM
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Fiber Data Sheet NZDF-Singlemodefiber (NZDF)
Non-Zero-Dispersion-Shifted Singlemode Fiber ITU-T G.655, ITU-T G.656; EN188000, EN1888100, EN1888101 PENGG KABEL offers non-zero dispersion shifted single mode optical fibers produced by the Vapour Phase Axial Deposition (VAD) method, which enables construction of high-capacy, ultra long haul WDM systems. This fibers allows the easier deployment of WDM in metropolitan areas, and increases the capacity of fiber in WDM systems throughout the wavelength region between 1460 nm and 1625 nm (S, C, L-bands, 1460 nm only for G.656 fiber). It’s non-zero dispersion caracteristic reduces four-wave mixing and cross-phase modulation over a wider wavelength range than conventional NZDF. Our NZDF fibers has the ability to increase transmission speeds of systems up to 10 Gb/s and 40 Gb/s and also has superior polarization mode dispersion performance.
Compostion core cladding coating
Germanium doped silica Silica Dual layers of UV-cured acrylate
Geometrical Characteristics core diameter d cladding diameter core/cladding concentricity error cladding non-circularity fiber curl radius primary coating diameter coating/cladding concentricity error Optical Characteristics attenuation
point discontinuity chromatic dispersion
at 1550 nm
at at at at at at at
1460 1550 1625 1550 1460 1530 1565
nm (only G.656) nm nm nm to 1625 nm (only G.656) to 1565 nm to 1625 nm
cut-off wavelength of cabled fiber PMD individual fiber link design value (typical) Mechanical Characteristics fiber proof test level macrobending loss for 100 turns at a 75 or 60 mm mandrel diameter 1 turn at a 32 mm mandrel diameter coating strip force dynamic fatigue resistance parameter Enviromental Characteristics induced attenuation at 1310 nm and 1550 nm from -60°C to +85°C temperature cycling 85°C / 98% RH temperature humidity cycling +85°C heating aging +23°C water immersion
at 1550 (and 1625 nm at G.655.a) at 1550 (and 1625 nm at G.655.a)
G.656 (G.655.c, e) 9.0 ±0.5 125.0 ±1.0 ≤0.7 ≥4 242 ±5 ≤12
G.655.a (G.655.d) 9.6 ±0.4 125.0 ±0.7 ≤0.5 ≤0.7 ≥4 245 ±5 ≤12
µm µm ≤0.5 % m µm µm
≤0.26 ≤0.22 ≤0.25 ≤0.10 2.0 bis 13.5 5.5 bis 10.0 7.5 bis 13.5 ≤1450
≤0.22 ≤0.25 ≤0.05 2.0 bis 6.0 4.5 bis 11.2 ≤1450
dB/km dB/km dB/km dB ps/(nm*km) ps/(nm*km) ps/(nm*km) nm
≤0.10 -
≤0.10 ≤0.04
ps/√km ps/√km
≥120
≥120
kpsi (1.2% strain)
≤0.05 ≤0.5 1.3 bis 8.9 ≥20
≤0.05 ≤0.5 1.3 bis 8.9 ≥20
dB dB N
≤0.05 ≤0.05 ≤0.05 ≤0.05
≤0.05 ≤0.05 ≤0.05 ≤0.05
dB/km dB/km dB/km dB/km
µm
Fiber Optic Cables
Common fiber type standard fiber describition
E8
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
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Fiber Data Sheet Multimodefiber (MM) OM 2 - Quality Common fiber type standard fiber describtion
G50
G50/125 according to VDE (Typ A1a), G50/125 according ÖVE or TA ITU-T G.651; EN188000, EN1888200, EN1888202; VDE0888/part 105, VDE0888/part 106, FZA TS0053/01 core consists of SiO2 doped with GeO2; optical cladding of quarzglass (SiO2); graded profile of the refraction index, matched cladding, phosphorus free; protective coating consisting of two layers of UV-cured acrylate resins
Mechanical Properties core diameter d core non-circularity core/cladding concentricity error cladding diameter cladding non-circularity cladding/coating concentricity error coating non-circularity fiber diameter
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level stripping force bending radius Optical Properties attenuation
band width attenuation (makrobending) attenuation alteration (range -60 up to +85°C) numeric aperture refraction index link lengths at 1 Gb/s
5
at at at at at
850nm 1300 nm 1383 nm 850 nm 1300 nm
at at at at at
850 nm 850 nm 1300 nm 850 nm 1300 nm
50 ±2.5 5.0 ≤1.5 125 ±2 1.0 ≤10.0 ≤6.0 245 ±10 265 ≥8 ≥100 ≤3.5 ≥30
µm % µm µm % µm % µm µm N kpsi N mm
≤2.5 ≤0.6 ≤2.0 ≥400 - ≥750 ≥500 - ≥1200 ≤0.5 ≤0.2 ≤0.2 ±0.015 1.4825 1.4775 ≥500 - ≥750 ≥550 - ≥2000
dB/km dB/km dB/km MHz*km MHz*km dB dB/km
(others on request) (others on request)
m m
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Fiber Data Sheet Multimodefiber (MM) OM 3 - Quality (OM 3+ , OM 4) Common fiber type standard fiber describition
G50
G50/125 according to VDE (Typ A1a), G50/125 according ÖVE or TA ITU-T G.651; EN188000, EN1888200, EN1888202; VDE0888/part 105, VDE0888/part 106, FZA TS0053/01 core consists of SiO2 doped with GeO2; optical cladding of quarzglass (SiO2); graded profile of the refraction index, matched cladding, phosphorus free; protective coating consisting of two layers of UV-cured acrylate resins
Mechanical Properties core diameter d core non-circularity core/cladding concentricity error cladding diameter cladding non-circularity cladding/coating concentricity error coating non-circularity fiber diameter
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level stripping force bending radius Optical Properties attenuation
refraction index attenuation (makrobending) attenuation alteration (range -60 up to +85°C) numeric aperture
at at at at at
850nm 1300 nm 1383 nm 850 nm 1300 nm
at 850 nm
50 ±2.5 5.0 ≤1.5 125 ±1 1.0 ≤10.0 ≤6.0 245 ±10 265 ≥8 ≥100 ≤3.5 ≥30
µm % µm µm % µm % µm µm N kpsi N mm
≤2.5 ≤0.7 ≤2.0 1.4825 1.4775 ≤0.5 ≤0.2 ≤0.2 ±0.015
dB/km dB/km dB/km
dB dB/km
Performance Characteristics
Upon request our fiber can be selected meeting inner mask radial specifications more stringent than the TIA/EIA-492 AAAC requirement: Inner mask: Rinner = 0 µm to Router = 18 µm Further to meeting the respective DMD template all OptiGrade fiber meets the additional requirement of IEC 60793-2-10 in the radial offset intervall masks, which sources out fibers, having rapid changes of the DMD. Transmission link lenghts 850 nm 300 400 500 550 m for 10 Gb/s* 1300 nm (LX4) 300 300 300 300 m *at 850 nm operating radius 4.5 µm ≤30 % wavelenth with transmitters radius 19.0 µm ≥86 % meeting encircled flux at
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Fiber Optic Cables
OptiGrade Classes 300 400 500 550 Bandwith 850 nm ≥1500 ≥2000 ≥2500 ≥3500 MHz*km (Overfilled Launch, LED based sources) 1300 nm ≥500 ≥500 ≥500 ≥500 MHz*km Effective Modal Bandwith 850 nm ≥2000 ≥2700 ≥4000 ≥4700 MHz*km Assured by: Differential Mode Delay (DMD) Fibers shall meet the respective DMD templates specified in or according to the standard TIA/EIA or IEC 60793-2-10, for transmitters meeting TIA/EIA-492 AAAC. Each template includes an inner and an outer mask requirement with: Inner mask: Outer mask: Rinner = 5 µm to Router = 18 µm Rinner = 0 µm to Router = 23 µm
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Fiber Data Sheet Multimodefiber (MM) Common fiber type standard fiber describition
G62,5
G62,5/125 according to VDE (Typ A1b), , G62,5/125 according ÖVE or TA EN188000, EN1888200, EN1888202; VDE0888/part 105, VDE0888/part 107, FZA TS0053/01 core consists of SiO2 doped with GeO2; optical cladding of quarzglass (SiO2); graded profile of the refraction index, matched cladding, phosphorus free; protective coating consisting of two layers of UV-cured acrylate resins
Mechanical Properties core diameter d core non-circularity cladding diameter core/cladding concentricity error cladding non-circularity cladding/coating excentricity coating non-circularity fiber diameter
uncoloured coloured
tensile strength according to EN 188000 PV201, 1s strain level stripping force bending radius Optical Properties attenuation
band width attenuation (makrobending) attenuation alteration (range -60 up to +85°C) numeric aperture refraction index link lengths at 1 Gb/s
7
at at at at at
850nm 1300 nm 1383 nm 850 nm 1300 nm
at at at at at
850 nm 850 nm 1300 nm 850 nm 1300 nm
62.5 ±2.5 5.0 125 ±2 ≤1.5 1.0 ≤10.0 ≤6.0 245 ±10 265 ≥8 ≥100 ≤3.5 ≥30
µm % µm µm % µm % µm µm N kpsi N mm
≤3.0 ≤1.0 ≤2.0 ≥160 - ≥250 ≥500 - ≥800 ≤0.05 ≤0.2 ≤0.275 ±0.015 1.4965 1.4920 ≥300 - ≥500 ≥550 - ≥1000
dB/km dB/km dB/km MHz*km MHz*km dB dB/km dB
(Standard 200) (Standard 600)
m m
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Letter Symbols - Fiber Optics Letter symbols according to VDE (outdoor cables)
Fiber Optic Cables
Letter symbols according to VDE (indoor cables)
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
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Colour Codes - Fiber Optics Colour Code - Fibers (Standard, others on request) Pengg Standard Fiber Colouring:
Ring Signing:
Colour Code - Tubes (Standard) 5-tubes construction
1xn
2xn
3xn
4xn
5xn
1xn
2xn
3xn
4xn
5xn
Singlemode Fibers NZDF-Fibers E8 Multimode Fibers G50
Multimode Fibers G62,5
no fiber assignment
6-tubes construction
6x n
Singlemode Fibers E9 NZDF-Fibers E8 Multimode Fibers G50
Multimode Fibers G62,5
no fiber assignment
9
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Types Signalling- and measuring cables
Switchboard cables
Signal and measuring cables are used for transmission of DC- and low Switchboard cables are used as connection between racks, main disfrequency AC-signals in telemetering-, signal-, clock- and paging tributors and switch stations in different kinds of railway offices (censystems as well as for control system (railway signals, signal boxes) tral offices, amplification bases and signal boxes). and for supervision systems. The cores are PVC-insulated. Cores are stranded together in layers; The cables consist of PE-insulated cores, which are stranded together shielded pairs, triples, quads or quintuples are stranded together in in concentric layers. The non-armoured types have a PVC-sheath over layers or units. The shielded types have a screening of aluminium lamithe cable core, the armoured types have a PVC-sheath (PE-sheath nated PET-foil (static shield) over the cable core, the switchboard according to ÖVE), a steel tape armouring and a PVC-outer protective cables have a PVC-sheath. cover.
Local outdoor telecommunication cables
Telecommunication switchboard wires
They are used in local telecom networks, for the connection of tele- They are used for switching and wiring of telecommunication instruphone sets to telephone exchanges and as connection cables in indu- ments and similar ones, i.e. telephone exchanges, amplification bases strial fields and in offices. and selection amplifiers. The cables have quads of PE-, foam-PE- or foam-skin-PE They consist of one or more twisted cores with PVC-insulation. insulated cores; the quads are stranded to unitss, the units are stranded to the cable core. The composite-layer sheath have a double-coated aluminium foil bonded with the PE-sheath. Petrol jelly fillings or swellable materials prevents water penetration along the cable. Shielded switchboard strands For special applications or customer-specifications the cables get They are used for switching of telecommunication instruments and additionally components, for example: similar ones, e.g. telephone exchanges, amplification bases and selection amplifiers. – PE-sheath, reinforced – steel tape or steel wire armouring Shielded switchboard strands consists of one or more twisted, PVC– PE or PVC protective cover insulated cores, a copper braid screening and a PVC-sheath. – aluminium laminated PET-foil instead of aluminium tape
Selfsupporting aerial cables
Telecommunication installation wires
Selfsupporting aerial carrier cables, so called SETRA cables, are used Telecommunication installation wires are used for switching of telewithin the telecommunication network of the PTTs as well as in the com instruments in dry and eventually dump areas. domain of private telecom and data transmission networks. They consists of one or more twisted PVC-insulated cores. They have PE-insulated quads cabled to units and if necessary a shielding of aluminium foil; cable core and a supporting rope of galvanized steel wires with common PE-sheath (e.g. PVC-sheath). Also available with quads stranded in layers.
Installation cables
Special cables for telecommunication
They are mainly needed for construction of telephone sets and exten- Telecom cables for very specified applications and different special sions and suited for fixed laying on dry and wet ground material indo- constructions (i.e. power protection cables, lightning protected teleor and outdoor. communication cables,railway signalling cables with inductive protection,...) belong to this field. The PVC-insulated pairs or quads are stranded together in layers or units. Depending on the type the cables are unshielded or shielded with an aluminium foil (static shield) and surrounded with a PVCsheath.
Cables for industrial electronics
Control cables
These cables are used for transmission of signals and measuring Control cables are used for transmission of analogue and digital sigvalues in units of the measuring, control and power electronic techni- nals. Special constructions have proven to work under difficult transques as well as for data processing. fer conditions and extreme severe environmental influences. They are composed of PVC-insulated cores or pairs stranded Main applications: industrial process control, refineries, fuel dumps, together into units. The shielded types have a screening of aluminium chemical industry, power plants, as well as in sciences and research foil or copper braid. The cables for industrial electronics have a PVC- work. sheath.
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
10
Letter symbols - copper cables Letter symbol
Description
Letter symbol
Description
AA AB AD-
outdoor cable (GE) aluminium shield (AT) outdoor cable with high voltage protection (GE) outdoor cable for power line protection (e.g. Differentialschutz) (GE) outdoor cable with inductive protection (GE) aluminium shield (DK) aluminium-PE laminated sheath (DK) armouring (AT/GE) cables with units (GE) one layer steel tape; ...mm thickness of steel tape (GE) protective cover of tarred jute (GE) shield (copper braid) (GE) shield (copper tape) (AT) copper conductor (DK) shield with stranded copper wires (GE) Dieselhorst-Martin quad (GE) drain wire (AT) filling of cable core (GE) quad with phantom utilization (GE) installation cable, flat design (GE) flat wire armouring (AT) telecomunication outdoor cable (AT) telecommunication indoor cable (AT) foil (DK) longitudinally aluminiumtape (GE) flat wire; thickness in ...mm (GE) conter helix (AT) mine cable (GE) skin (in foam-skin insulations) (AT) peak value of mutual capacitance [nF/km] (GE) cable core jelly filled (AT) installations cable (GE) installations cable for industrial electronics (GE) element with metallic foil and drain wire (AT/GE) additionally corrosion proofing over armouring (GE) innersheath and shield of londgitudinally copper tape (GE) coax pair (AT/GE) design with resistance to cold (GE) smooth aluminium tape (GE) laminated aluminium tape (GE) composite layer sheath (GE) sheathed flexible cable (GE) corrugated aluminium sheath (GE)
LG LI M MZ 2M (M...) OF P P PAP PE perf Q (R...) R S SSSMPE SPE ST
cabling in layers (GE) stranded or bunched conductor (GE) lead sheath (AT/GE) lead sheath with addition of setting (GE) lead sheath with addition of setting (AT) max. mean value of mutual capacitance [nF/km] (GE) filling of cable core with special material (GE) paper insulation (AT/GE) pair (GE) paper (wrapping) (DK) polyethylene (outer) sheath (DK) perforated (GE) steel wire braid (AT/GE) round wire; diameter in ... mm (GE) round wire armouring (AT) railway signalling cable (GE) switchboard cable (GE) railway signalling cable (AT) foam-skin-PE insulation (DK) foam-PE insulation (DK) quad in cables for long distances and phantom utilisation (GE) quad in cables for long distances (GE) quad in local telecommuncation cables (GE) set value of mutual capacitance [nF/km] (GE) static shield of metallic tape or aluminium laminated pet-foil (GE) suspension wire (AT/GE) carrier frequency quad (GE) swelling material (GE) tinned copper wire (AT) filling of cable core (DK) tinned (GE) corrugated steel sheath (GE) PVC insulation, sheath or protective cover PVC (AT/GE) PVC sheath or protective cover, reinforced (GE) PVC sheath or protective cover, reinforced (AT) steel- or PA-braid, rssistant to extension (GE) glass yarn strength members (GE) PE isulation, sheath or protective cover (AT/GE) PE sheath or protective cover, reinforced (GE) PE sheath or protective cover, reinforced (AT) foam-PE insulation (AT/GE) foam-skin-PE insulation (AT) foam-skin-PE insulation (GE)
AJAL AL+PE B BD (1B...) C C C CU D DM E F F F F FFIFOL (FA) (F...) G GH (H...) J JJE...IMF -K (K) Kx KF L (L) (L)2Y LLD
ST I ST III (S...) (ST) T TF TF V VAS vzn W Y YV Y3V (Z) (ZG) 2Y 2YV 2Y3V 02Y 02YH 02YS
Examples for telecommunication cables A-02YSF(L)2Y 200x2x0.8 ST III BD Longitudinally waterproof local telecommunication cable with 100 foam-skin PE insulated quads, bare copper conductor, diameter 0.8 mm, stranded to units, jelly filled, paper tape covering and composite layer sheath; (similar to FTZ). J-Y(ST)Y 20x2x0.6 LG Installation cablel with 20 PVC-insulated pairs, bare copper conductor, diameter 0,6 mm, stranded in layers, plastic tape wrapping, static shield PETP aluminium foil with drain wire and PVC-sheath; (according to VDE 0815). A-2YYBY 16x1x0.9 S LG Railway signal cable with 16 PE insulated cores, stranded in layers, bare copper conductor, diameter 0.9 mm, plastic tape wrapping, PVCsheath, stell tape armouring and PVC protective cover (according to VDE 0816/part 2). 11
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Basic Formulas of Telecommunication Technique Units Term
Symbol
Letter symbol
angular frequency attenuation (equivalent) attenuation coefficient capacitance load per unit length capacitance unbalance conductivity conductance conductance per unit length conductor cross section conductor resistance current, strength of current dissipation factor frequency group delay inductivity inductivity load per unit length insulation resistance image phase change coefficient impedance (amount) impedance (complex) impedance (imaginary part) impedance (real part) line length level magnetic unbalance mutual capacitance mutual inductance near end cross talk attenuation (equivalent) phase delay power reduction factor reflection coefficient relative permittivity resistance load per unit length specific resistance temperature velocity of propagation voltage wave length
ω a, α α C’ k, / k1 / k2,3 /k9-12 / e1,2 κ G G’ q R I tan δ f τg L L’ Ris β Z ZL Zi Zr l p m C M a n, α n τp P rk r εr R’ s t vü U λ
s-1 dB (Np) dB/km (Np/km) F/km pF Sm/mm² mS/km S/km mm² Ω/km A Hz s/km mH/km H/km MΩkm rad/km Ω Ω Ω Ω km dB (Np) nH nF/km mH/km dB (Np) s/km W Ω/km Ωmm²/m °C bit/s V m
Unit 1/second dezibel (neper) dezibel (neper)/km farad/km pikofarad siemensmeter/mm² millisiemens/km siemens/km millimeter² ohm/km ampere hertz second/km millihenry/km henry/km megaohmkilometer rad/km ohm ohm ohm ohm kilometer dezibel (neper) nanohenry nanofarad/km millihenry/km dezibel (neper) second/km watt ohm/km ohm mm²/m degree celsius bit/second volt meter
Basic formulas for homogeneous, symmetrical cables Conductor resistance Rt R20 t k
Complex characteristic impedance
resistance at t °C in Ohm resistance at 20°C in Ohm temperature in °C 0.00393 for Cu or 0.00403 for Al
Angular frequency
Dissipation factor
(Ω)
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
12
Basic Formulas of Telecommunication Technique Basic formulas for homogeneous, symmetrical cables Impedance (amount) at low frequencies (voice frequency)
Impedance (amount) at high frequencies (ω L>R)
(Ω)
(Ω)
L C
Attenuation at low frequencies (voice frequency)
inductivity (H/km) mutual capacitance (F/km)
Attenuation at high frequencies (w L>R)
(Np/km)
(dB/km)
13
(Np/km)
R G
loop resistance (Ω/km) conductance (S/km)
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Shifting Guideline Bending radius When laying and bending the cables as well as at the mounting points (e.g. brackets) the bending radius R may not come up to those below stated. When forming out the cables during the assembly of appropriate treatment the minimum bending radius may be reduced at the most to half of the indicated values. Cable typ installation cables, switchboard cables
Bending radius R minimum value 7.5 x DA
outdoor cables with composite layer sheath 7.5 x DA outdoor cables
10 x DA
DA .... cable outer diameter
Installation temperature For the transfer not the ambient temperature but the temperature of the cable is determining. With low ambient temperatures cables can be warmed up before shifting by suitable measures in such a way that the cable inside is not cooling under the permissible shifting temperature during the entire shifting procedure. Stress and jerks as well as stress by impact are to be avoided at low temperatures. The pulling speed of the cables should be as even as possible. temperature range during installation: cables with Polyethylene sheath (PE) cables with Polyvinylchlorid sheath (PVC)
-20ºC up to +50ºC -5ºC up to + 50ºC
Tensile load for control- and telecommunication cables
(according to VDE 0891/part 6)
The tensile stress indicated in the following tables applies uniformly to all for with guaranteeing tensile strength armouring cable, with which is included the cable core frictional connected with the cable sheath - either over a tie rod with pulling eye or a firmly mounting pulling trunk.
Number of
Maximum allowed value of tensile load [N]
cores Conductor diam.
4 5 8 12 16 21 27 33 40 48 56 65 75 80 96 108 114 133 147 154 176 200
0.9 100 150 250 350 500 650 800 1000 1200 1450 1650 1950 2200 2350 2800 3100 3250 3700 4000 4200 4700 5300
1.4 300 400 600 900 1200 1500 1900 2300 2700 3200 3700 4300 4800 5100 6000 6800 7100 7900 8600 8900 9900 11000
1.8 500 650 1000 1450 1900 2400 3100 3700 4400 5300 5800 6700 7600 8000 9200 10000 10600 12000 13000 13500 15200 17000
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
14
Shifting Guideline Tensile strength of telecommunication outdoor cables with guaranteeing tensile strength resistance Number of
Maximum allowed value of tensile load [N]
double cores Conductor diam.
5 6 10 20 30 40 50 60 70 80 100 120 150 200 250 300 350 400 500 600 700 800 1000 1200 1500 2000
0.4 250 300 400 500 650 750 850 1000 1100 1400 1600 2000 2600 3300 3900 4300 4900 5900 6800 7600 8400 9800 11000 12500 14400
0.6 350 400 500 700 950 1200 1500 1700 2000 2300 2800 3400 4100 5200 6400 7400 8600 9600 11500 13200 14500 15500 17500 19000
0.8 600 1000 1500 2000 2500 2900 3400 3800 4600 5400 6600 8500 10000 11500 13000 14500 17000 19000 20500 21500
0.9 700 1300 1900 2500 3000 3500 4100 4600 5700 6600 8000 10000 12000 13500 15000 16300 18700
1.2 1200 2300 3200 4100 5000 6000 6700 7500 9000 10500 12500 15700 18800 20000
1.4 1600 2800 4000 5200 6400 7500 8500 9500 11400
The values in the tables above refer to unarmoured cables with no guaranteeing tensile strength armouring. If higher traction loads are necessary, cables with a a garanteeing tensile strength armouring (steel round or rectangular wire) are to be planned. For the calculation of the tensile load for such cables applies an approximate value of 12 daN for each mm2 steel cross section.
15
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Common Explanations Pictograms Copper Cables All datasheets are signed with common pictograms, which describe the cable make up and will lighten the localisation of the most applicable cable type.
Mutual capacitance C35
C38
C42
C50
C52
C55
C60
Dimension of copper conductor conductor diameter [mm] Ø 0,4
Ø 0,5
Ø 0,6
Ø 0,8
triple
quad
Ø 0,9
Ø 1,0
Ø 1,2
Ø 1,4
Ø 1,8
cross section [mm2]
Cable elements core
pair
quintuple
pair in metal foil “PIMF”
Number of double cores (DC) DC, talking circuit DC 4
DC 2-4
DC 4-8
DC n
Filling unfilled
petrol jelly
Füllnidz
dry filling / swellable materials
Overall screening, armouring unshielded
foil
copper braid or tape
foil and copper braid
copper wires
composite layer (L)
armouring (steel tape, round steel wires)
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
16
Common Explanations Pictograms Fiber Optic Cables Construction metal-free
halogenfree, flame retardant rodent protection
longitudinally water-tight
Application indoor cable
outdoor cable
aerial cable (ADSS)
Characteristic features of insulation and sheath materials Material
Resistance to break-down [kV/mm]
Spec. volume resistance [Ωcm]
Continous possible operating temperature dauernd [°C]
PVC (standard compound) PVC (compound for telephon cores) LDPE HDPE Foam-PE
25 25 70 85 60
1013 1015 1017 1017 1017
–20 –10 –50 –50 –50
Material
Operating temperatur (short time) [°C]
Decompositionor distortiontemperature [°C]
Inflammability
PVC (standard compound) PVC (compound for telephon cores) LDPE HDPE Foam-PE
+100 +100 +100 +120 +90
+120 +120 +110 +130 +110
self-extinguishing self-extinguishing inflammable inflammable inflammable
Material
Waterabsorption %
Weatherproof
Chemical resistance (general)
Radioresistance x106 rad
PVC (standard compound) PVC (compound for telephon cores) LDPE HDPE Schaum-PE
0.4 0.4 0.1 0.1 0.1
good good good limited good
limited limited limited good limited good limited good
17 17 19 19 19
Material
Relative permittivity ε
Density
5–8 3–4 2.3 2.3 1.6
PVC (standard compound) PVC (compound for telephon cores) LDPE HDPE Foam-PE
17
up up up up up
to to to to to
+70 +70 +70 +90 +70
[g/cm3]
Tensile strength [MPa]
Breaking elongation %
Lettersymbol
1.45 1.4 0.92 0.945 0.65
15 20 20 25 10
250 200 400 500 500
Y Y 2Y 2Y...HD 02Y
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Common Explanations RAL-colour code colournumber
colour
hueexpresion
colournumber
colour
hueexpresion
1001 1012 1013 1014 1015 1016 1019 1021 2000 2002 2003 2004 3000 3002 3004 3015 4001 4003 4005 5002 5010 5012 5014
beige yellow white ivory beige yellow beige yellow orange orange orange orange red red red pink violet violet violet blue blue blue blue
beige lemon yellow oyster white ivory light ivory sulfur yellow grey beige rape yellow yellow orange vermilion pastel orange pure orange flame red carmine red purple red light pink red lilac hether violet blue lilac ultramarine blue gentian blue light blue pigeon blue
5015 5019 6000 6001 6003 6005 6010 6018 6027 7000 7001 7021 7032 7035 7037 8003 8011 8014 8024 9001 9005 9007 9010
light blue blue green green green green green green turquoise grey grey grey grey (ptt grey) grey grey brown brown brown brown white black silver grey white
sky blue capri blue patina green emerald green olive green moss green grass green yellow green light green squirrel grey silver grey black grey pebble grey light grey dusty grey clay grey nut brown sepia brown beige brown cream jet black grey aluminium pure white
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
18
Behaviour in Case of Fire, Fire Away Line, Fire Load Requirement In the European standards EN 50167, EN 50168 and EN 50169 data cables with halogen-free outer sheath are required. The consideration and adherence to these standards are recommended particularly with public setting e.g. hospitals, schools and airports. In addition with other buildings with high person or real value concentration a use of halogen-free cables is practical.
Cable with PVC-sheath In the case of fire standard PVC materials can transmit fires and form hydrochloric acid (HCI) by splitting off hydrogen chloride gas in connection with moisture (e.g. fire fighting water). It continues to come to a strong smoke development with burning PVC (polyvinyl chloride) and the corrosive damage at buildings and equipment can often devastating extents assume, which exceed far the actual fire damage.
Testing method according to IEC 60332-1 Samples From the end of the tested cable a sample piece of 600±25 mm is taken. Preparation (fig.1) Propane from cylinder with burner, flame height 175 mm. Sample is hung up vertically into the center of a metal box, (metal box: h=1200±25 mm, b=300±25 mm, t=450±25 mm, front open). Flame cone of the gas burner has to be fixed in an angle of 45° approx. 100 mm above the lower sample. With cable diameter up to 50 mm one burner is used, with cable diameter over 50 mm two burners are used. Execution
m t = 60 + —— 25
t = duration of the flaming action in s m = weight of the sample in g
Cables with halogenfree sheath Hereby materials are used, which do not contain halogens (e.g. chlorine) and which do not set free corrosive gases in the case of fire. Also the proportion of toxic gases is reduced to a minimum, and smoke development and fire away line are hardly still available or possible. Designation notes at the cable are e.g. the abbreviations FRNC or LSOH. In detail these designations are meaning: FR – flame retardant (fire-away-line-restraining) NC – non corrosiv (no corrosive constituents) LS – low smoke (low smoke development) 0H – zero halogen (halogen-free) Another big advantage by using such materials is, that the free view on gears and escape routes is kept. Please note that you have to take care that such kinds of materials are also used by other products, e.g. power cables or cable run channels.
Fire load [kWh/m], [MJ/m] In each building there are many different inflammable installations or products. Also cable and cores (although hidden in intermediate ceilings or channels), which can in particular represent a substantial component in administration buildings belong to them. These cables have most divergent powers (heat values) and the total fire load of a building could clearly increase. Therefore you should be pay attention to the fact, when planning that the fire load quantities are kept as small as possible.
19
Analysis The test is considered as positively passed if the sample did not burn or the flames automatically go out and the fire damage does not reach the upper end of the sample. Fire-pure e.g. soot lining and colour modification are not does claimed.
Testing method according to IEC 60332-2 Samples From the end of the tested cable a sample piece of 600±25 mm is taken. Preparation Propane from cylinder with burner, flame height 125 mm. Sample is hung up vertically into the center of a metal box, (metal box: h=1200±25 mm, b=300±25 mm, t=450±25 mm, front open). Flame cone of the gas burner has to be fixed in an angle of 45° approx. 100 mm above the lower sample. Execution max. 20s Analysis The test is considered as positively passed if the sample did not burn or the flames automatically go out and the fire damage does not reach the upper end of the sample. Fire-pure e.g. soot lining and colour modification are not does claimed.
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Behaviour in Case of Fire, Fire Away Line, Fire Load Testing methodes according to IEC 60332-3 Samples From the end of the tested cable sample pieces of 360 mm are taken. The number of samples depends on the cable diameter.
Testing method 1
Testing methode 3
Preparation (fig. 2) The samples are arranged at the test rack as follows: Telecommunication cables and cords as well as control cables and cords with an outside diameter ≤30 mm without distance. The number has to be selected in such a way that the grouping width results of min.180 mm; the distance of the outside samples to the lateral side piece of the ladder should be approx. 90 up to 120 mm; mounting of the samples with steel wires; the test rack is inserted vertically into the suspension of the furnace. Dimensions of the furnance as well as air volume and temperature are exactly regulated. Burner, 77.7±4.8 l/min propane and 13.5±0.5 l/h air measured at 20°C and 1 bar. Before starting the test the test set-up has to be conditioned at room temperature for mind. 16 h. Flame of the gas burner has to be fixed in an angle of 90° approx. 600 mm above the lower sample end, in a distance of 75 mm. Execution Duration of the flaming action at least min. 20 minutes
Fig.1
Fig.2
The test according to test type 3 shows very realistically the possible fire in a vertical duct.
Analysis The test is considered as positively passed if the sample did not burn or the flames automatically go out and the fire damage does not reach the upper end of the sample. Fire-pure e.g. soot lining and color modification are not does claimed.
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
20
Nominal Data of Wooden Drums (DIN 46391) Drums according to DIN 46391 (dimensions, weights)
identification number
drum dimesion
flange-diameter D [mm]
barrel-diameter width d B [mm] [mm]
traverse width carrying b capacity [mm] aprrox. [kg]
drumweight aprrox. [kg]
051 E6 061 071 E8 081 091 E10 101 E12 121 E14 141 E16 161 162 E18 181 182 E20 201 202 E22 221 222 E24 250 251 252 E26 E28 281 E30
05 06 06 07 08 08 09 10 10 12 12 14 14 16 16/8 16/10 18 18/10 18/12 20 20/12 20/14 22 22/14 22/16 24 25/14 25/16 25/18 26 28 28/18 30
500 600 630 710 800 800 900 1000 1000 1200 1250 1400 1400 1600 1600 1600 1800 1800 1800 2000 2000 2000 2200 2240 2240 2400 2500 2500 2500 2600 2800 2800 3000
150 300 315 355 400 400 450 550 500 700 630 850 710 1000 800 1000 1150 1000 1250 1300 1250 1400 1450 1400 1600 1600 1400 1600 1800 1700 1800 1800 1900
400 – 315 400 – 400 560 – 560 – 666 – 660 – 844 835 – 835 825 – 1035 1030 – 1140 1130 – 1140 1130 1120 – – 1280 1270
8 20 13 25 40 31 47 80 71 150 144 200 175 350 280 271 500 380 352 600 550 544 700 710 738 900 875 900 909 1100 1400 1175 1600
470 450 415 500 560 500 670 700 690 790 860 870 870 970 1060 1100 1110 1060 1100 1190 1310 1345 1330 1410 1475 1380 1450 1450 1475 1450 1650 1590 –
– – 250 400 – 600 800 – 900 – 1700 – 2000 – 3000 3000 – 4000 4000 – 5000 5000 – 6000 6000 – 7500 7500 7500 – – 10000 10000
up to drum dimension 10 with cable bushing
21
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
Nominal Data of Wooden Drums (DIN 46391) Capacity (spooling length in m) identification number 061 071 081 091 101 121 141 161 162 181 182 201 202 222
cable diameter in millimeter [mm] 6 7 8 9 10
cable-diameter 6 - 23 mm 11
12
13
14
15
16
17
20
21
22
93 165 219 402 576 1139 1352 2435 1849 2831 2772 2405 2076 1985
90 159 211 387 485 991 1304 2172 1600 2527 1704
122 167 315 468 856 1145 1931 1539 2248 1636
Capacity (spooling length in m) identification number 081 091 101 121 141 161 162 181 182 201 202 221 222 250 251 252 281 282
121 141 161 162 181 182 201 202 221 222 250 251 252 281 282
19
cable diameter in millimeter [mm] 24 25 26 27 28 156 294 377 709 967 1657 1278 1927 1343 2608 2096
151 285 365 688 839 1608 1235 1867 1295 2522 2023
32
33
34
209 428 537 866 655 1009 779 1500 1081 2035 1553 2978 2976 2893 2558 2491 2944 2848 2474 2398 2327 2004 1948
204 352 451 846 638 985 635 1289 1052 1984 1511 2908 2428 1896
344 441 828 622 962 618 1257 1024 1726 1264 2605 2134 1614
116 228 299 668 814 1419 1053 1650 1093 2218 1732
221 290 567 700 1244 1020 1450 1057 2150 1675 2861 2881 2493 2408 2329
215 282 551 681 1211 860 1409 1023 1879 1418 2777 2000
cable diameter in millimeter [mm] 42 43 44 45 46 190 259 529 348 61S 415 779 577 1107 877 1633 1406 963 1995 1666
254 437 341 511 315 763 565 1085 699 1603 1199 942 1956 1401
249 430 334 502 309 749 553 1064 684 1574 1175 923 1693 1373
245 422 328 492 302 611 542 890 670 1373 1153 904 1661 1345
240 415 321 484 296 600 531 874 657 1349 1131 886 1630 1319
23
117 161 304 389 827 999 1869 1324 2172 1394 2953 2629 2524 2176 2992
cable-diameter 24 - 41 mm 29
30
31
209 226 462 663 1180 835 1371 851 1826 1374 2450 1939
162 220 450 564 1028 811 1197 825 1583 1333 2383 1882
214 438 550 1003 789 1166 802 1540 1295 2089 1598
35
36
37
38
39
40
41
336 431 707 607 824 603 1227 998 1685 1232 2547 2083 1573 2890 2737 2663 2594 2242
329 422 692 493 806 587 1041 816 1646 1201 2271 2035 1534 2822 2186
265 348 678 482 788 466 1017 796 1418 1170 2223 1774 1286 2759 2134
259 341 664 471 772 454 994 777 1386 960 1969 1735 1255 2432 2084
254 334 560 460 653 444 972 759 1356 938 1930 1697 1226 2379 1780
249 327 549 451 640 434 812 742 1328 917 1892 1466 1199 2329 1740
244 264 539 356 627 424 795 590 1130 896 1664 1435 1172 2036 1702
Capacity (spooling length in m) identification number
18
1113 845 637 472 386 314 253 237 189 179 140 134 102 97 2024 1481 1064 892 677 564 468 385 364 297 239 228 218 172 2755 2340 1463 1152 980 761 643 542 454 430 358 294 281 228 2731 2202 1768 1404 1206 1032 881 749 632 603 505 485 2866 2349 1912 1540 1339 1159 1000 860 736 705 599 2727 2255 1991 1756 1545 1355 1784 2967 2479 2205 1959 1737 1535 2722 2903 2543 2220 2123
cable-diameter 42 - 59 mm 47
48
49
50
51
52
53
54
55
56
57
58
59
187 408 330 325 319 314 310 305 243 238 234 230 226 222 218 214 151 149 146 475 386 380 373 367 361 356 280 276 271 267 290 285 279 274 195 191 188 184 181 178 175 589 578 568 558 442 435 428 421 414 408 401 405 397 389 382 375 369 362 356 254 249 245 858 842 828 678 666 655 644 634 624 614 488 644 632 620 474 465 457 449 441 434 426 419 1326 1144 1125 1107 1089 1072 912 898 885 872 860 1110 931 914 898 883 869 713 701 690 679 668 708 694 681 668 656 645 633 48S 477 469 461 1600 1367 1343 1320 1298 1276 1073 1073 1039 1022 1006 1293 1065 1046 1026 1008 990 973 779 766 753 741
144 263 172 304 241 480 413 719 658 454 991 729
142 260 169 300 237 473 29S 709 649 446 815 718
Technical Information • 08/2013 • © by PENGG KABEL GmbH • Subject to technical alterations
22
