GJYXFCH-FTTH Flat Drop Cable 2.0×5.2mm

GJYXFCH-FTTH Flat Drop Cable 2.0×5.2mm

Cable Specifications:

· Cable Type: GJXH-1, GJXH-2, GJXH-4 (Single Core, 2 Core, 4 Core)

· Fiber Type: G.657.A2

· Fiber Colors:

o GJXH-1: Blue

o GJXH-2: Blue, Orange

o GJXH-4: Blue, Orange, Green, Brown

· Cable Diameter: (2.0 ± 0.05) x (3.0 ± 0.1) mm

· Load-bearing Strength Member: None

· Cable Strength Member: Phosphated Steel (2 strands, 0.40mm)

· Outer Sheath Material: LSZH (Low Smoke Zero Halogen)

Mechanical Specifications:

· Minimum Bending Radius:

o Operation: 30D (where D is the cable diameter)

o Using: 15D

· Tensile Strength:

o Long-term: 100N

o Short-term: 200N

· Crush Strength:

o Long-term: 1000N/100mm

o Short-term: 2000N/100mm

Optical Characteristics:

· Attenuation:

o 1310nm: ≤0.36dB/km

o 1550nm: ≤0.22dB/km

· Cut-off Wavelength: ≤1260nm

Environmental Characteristics:

· Storage Temperature: -40°C to +70°C

· Operating Temperature: -30°C to +60°C

■ Cross Section:

 

■ Printing on Sheath:

• ZION: Manufacturer’s brand (can be customized to the client's brand if needed).

• 2024: Year of manufacture.

• FTTH: Type of cable (Fiber to the Home).

• XX (G.657A): Number of cores (e.g., 1 core, 2 cores, etc.) with the fiber type specified as G.657A (a single-mode optical fiber standard).

• XXXXm: Length of the cable in meters.

*The marking is printed every 1 meter;

● The color of marking is white, but if the remarking is necessary, the yellow color marking shall be printed newly on a different position.
● An occasional unclear of length marking is permitted if both of the neighboring markings are clear;
● The both cable ends are sealed with heat shrinkable end caps to prevent water ingress.

■ Fiber Properties:

The properties of single mode optical fiber (ITU-T Rec. G.657)

Physical Characteristics:

· MFD (Mode Field Diameter) at 1310nm: 8.2 - 9.0 mm

· Cladding Diameter: 125.0 ± 0.7 mm

· Cladding Non-circularity: ≤ 1.0% (ensures the cladding is nearly circular)

· Cladding to Core Concentricity Error: ≤ 0.5 mm (ensures proper alignment between the core and cladding)

· Secondary Coating Diameter: 245.0 ± 10.0 mm

· Secondary Coating to Cladding Concentricity Error: ≤ 12.0 mm

· Fiber Curl: ≥ 4.0 m (indicates minimum allowable radius for fiber bending)

Optical Performance (Attenuation) at Various Wavelengths:

· At 1310nm: ≤ 0.34 dB/km

· At 1383nm: ≤ 0.31 dB/km

· At 1383nm (after H2 aging): Δ ≤ 0.01 dB/km (indicates minimal degradation after aging)

· At 1550nm: ≤ 0.20 dB/km

· At 1625nm: ≤ 0.23 dB/km

Discontinuity:

· Point Discontinuity at 1310nm and 1550nm: ≤ 0.02 dB (ensures minimal discontinuities at these wavelengths)

Cut-off Wavelength (λc):

· At 1310nm: 1150 ≤ λc ≤ 1330 nm (indicates the operational range for fiber cut-off)

Zero Dispersion Wavelength (λ₀):

· At 1310 - 1324 nm: 1300 - 1324 nm (range of wavelengths with minimal chromatic dispersion)

Chromatic Dispersion (D(λ)):

· At 1288-1339 nm: ≤ 3.5 ps/(nm·km)

· At 1271-1360 nm: ≤ 5.3 ps/(nm·km)

· At 1550 nm: ≤ 18 ps/(nm·km)

· At 1625 nm: ≤ 22 ps/(nm·km)

Polarization Mode Dispersion (PMD):

· Fiber PMD: ≤ 0.2 ps/km¹/²

· Link PMD: ≤ 0.1 ps/km¹/² (for longer transmission distances)

● Attenuation vs. Wavelength maximum increase of the att. in 1285-1330nm reference the att. at 1310nm 0.03dB/km; maximum increase of the att. in 1525-1575nm reference the att. at 1550nm 0.02dB/km.
● Attenuation from out end- attenuation from inner end 0.05dB/km ; max segment loss-avg loss0.03dB/km.(OTDR)

■ Mechanical Characteristics:

Proof Stress Level:

· Strain: ≥ 2.0% (indicates the strain at which the proof stress is defined)

· Proof Tension Stress: ≥ 19.76 N (the force at which the fiber undergoes permanent deformation)

Allowable Bending Radii:

· 15 mm (the minimum radius the fiber can be bent without damaging it)

Additional Attenuation with Bending:

· For 10 turns with D=30mm:

o At 1550 nm: α ≤ 0.25 dB

o At 1625 nm: α ≤ 1.0 dB

· For 1 turn with D=20mm:

o At 1550 nm: α ≤ 0.75 dB

o At 1625 nm: α ≤ 1.5 dB

o These values represent the additional signal loss (attenuation) induced when the fiber is bent. A smaller bending radius or more turns results in higher attenuation.

Coating Strip Force:

· Peak Value (F): 1 ≤ F ≤ 8.9 N (force required to strip the coating)

· Average Value (F): 1 ≤ F ≤ 5 N (average stripping force required)

Dynamic Fatigue Test (Nd):

· Nd ≥ 20 (a measure of the fiber's resistance to dynamic fatigue, indicating the number of cycles the fiber can withstand under stress before breaking)

Tensile Test, Breaking Strength (sf(0.5)):

· sf ≥ 3.8 GPa (the breaking strength of the fiber, measured in gigapascals, indicating the fiber's ability to withstand tension)

■ Packing and Marking:

Packing

● Each single length of cable shall be reeled on Plastic Drum.

● Drum length: Standard drum length is 3000m±2% or design as per client inquiry ;

 

Drum Marking (can according to the requirement in the technical specification)

-Manufacturer name;

-Manufacturing year and month;

-Roll-direction arrow;

-Cable outer end position indicating arrow;

-The word “OPTICAL FIBER CABLE”;

-Cable type and size;

-Drum number;

-Drum length;

-Gross / net weight;

-Origin, The word “MADE IN CHINA”;

-Caution plate indicating the correct method for loading, unloading and convey the cable;

-Other customer information such as contract no., project no., and delivery destination. (if needed)

 

Cable identification documents

-Product qualified certificate;

-Test report.

■ Round Cables (Indoor Flexibility & Fire Safety)

Models: GJYFJHH, GJYFJH, GYFJU 

• The installation of fire-safe indoor FTTH cables calls for space-saving, cable-style design. 

• LSZH Sheath → Abates the harsh fire emanation for increasing safety of the environment. Flexible & Varying Diameters → However, an additional advantage to the use of such cables in a tight indoor space is that routing them through walls, floors, and conduits becomes much easier. 

• Best For: Vertical structures, complexes, or closely situated inner areas of a building where hiding cables is preferred for consistency with the building's appearance and design regulations.

■ Flat Cables (Lightweight & Durable FTTH Solutions) 

Models: GJXFH, GJXH, GJXH Small, GJXFDH/GJXDH, FDC 

• Cables used in FTTH networks must be lightweight for convenience, yet robust enough to endure various environmental conditions during both indoor and outdoor applications. 

• Lightweight Non-metallic BRP Frabicated FRP for Internal Use 

• Metallic Steel Members for Sturdiness and Reliability under Extreme Conditions 

• Increased Fiber Count Contained in Small Mountable Ducts Suitable for Fast High Capacity Links (with illustrational labels) 

• Negligible Profile for Viability under Carpets, Walls, or Ducts in Construction Sites whatever, Indoor/Outdoor purposes. 

• Best For: Used for residential places, offices, or commercial installations for flexible routing with overlaying or underlaying minimum structures.

 

■ Self-Supporting Cables (Aerial Deployment)

Models: GJYXCH, GJYXFCH, GJYXFDCH/GJYXDCH, ASU, GYXY-8S, GYFXBY

• FTTH networks, which are established for aerial deployments, are required to have cables that persist heavy-duty use, do not corrode, and can cover a wide span without “sagging.” 

• Steel or FRP Messenger: Used Fulfillment of High Flyers to have Requested Strength. 

• Best For: Greatly suitable for aerial FTTH deployments that are on a longer span and need endurance and reliability.

 

■ Specialized Outdoor Cables (Aerial/Duct Durability) 

Model: GYGXY

• In comparison to those in indoor environments, outdoor cables are exposed to UV light, moisture, and rodents, making them vulnerable to harsh climate effects.

• Non-metallic Glass Yarn Reinforcement: Contributes to lightweight with anti-corrosion qualifications, which can last a long time. 

• HDPE Sheath: UV-resistant, moisture-proof, and rodent-resistant guarantee plus durability.

• Best For: The cables for outdoor FTTH installation in aerial or duct settings that are required for long-term use.