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GJPFJV
Cytech
Product Description
The GJPFJV indoor optic fiber cable uses multiple tight-buffered optical fibers as the basic unit,high modulus aramid yarn as the reinforcing element,and the sheath is made of polyvinyl chloride(PVC) or low-smoke halogen-free flame -retardant polyolefin(LSZH).
•Soft,small bending radius,easy to strip fiber;
•High strength aramid yarn offers high tensile strength;
•Good flame retardant properties;
•It's available under high and low temperature;
•Meet the various requirements of the market and users.
Applications: Indoor pipe wiring system,tomake patch cord and pigtail,connecting for indoor equipment;
Working temperature:-20℃~+60℃;
Bend Radius: Static 10 times the cable diameter,
Dynamic 20 times the cable diameter.
YD/T 1258.4-2019 Indoor optical fibre cables-Part 4 Multi-fibre optical cables
Fiber count | Cable Diameter(mm) | Cable Weight(KG/KM) | Max.tensile strength(N) | Max.Crush resistance(N/100m) | ||
Short Term | Long Term | Short Term | Long Term | |||
4 | 4.8 | 17 | ≥660 | ≥200 | ≥1000 | ≥200 |
8 | 5.8 | 30 | ||||
12 | 6.3 | 38 | ||||
24 | 8.5 | 60 | ||||
GJPFJV indoor optical fiber cable.pdf
Fiber strippers, splicing kit (fusion/mechanical), OTDR/power meter, cable ties (preferably Velcro), labels, isopropyl alcohol, lint-free wipes, PPE (gloves, safety glasses).
Ensure cables meet fire ratings (e.g., LSZH for low smoke) and local building codes. Check manufacturer specs for bend radius (typically 10x cable diameter) and tensile strength.
Avoid sharp bends; maintain minimum bend radius (e.g., 30 mm for typical cables).
Use cable trays/conduits; avoid sharp edges, heat sources, and high-traffic areas. Keep 50–100 mm separation from electrical cables.
Use swivel hooks/fish tape to prevent twisting. Limit tension (≤ manufacturer’s rating, often 50–100 N).
Use Velcro ties or cushioned clips every 0.5–1 meter. Avoid overtightening.
Clean LC/SC/ST connectors with alcohol/wipes. Use pre-terminated cables or splice carefully (fusion for low loss, mechanical for quick fixes).
Cut aramid yarn with precision; avoid damaging fiber coating.
Verify connections with OTDR/power meter (loss ≤ 0.3 dB per connector).
Mark endpoints, splice points, and panels. Update network diagrams.
Check monthly for physical damage, bends exceeding radius, or loose ties.
Inspect connectors quarterly for contamination; clean as needed.
Biannual OTDR tests to monitor attenuation changes. Investigate spikes >0.5 dB.
Ensure temperature/humidity remain within manufacturer specs (typically -10°C to 60°C, <85% RH).
Train personnel on handling, cleaning, and emergency repairs.
Clean connectors, check bends/splices, replace damaged fibers.
Re-splice or replace affected sections; use conduit in high-risk areas.
Inspect connectors for cracks; ensure proper seating.
Use LSZH-rated cables in plenum spaces.
Required if cable contains metallic elements (e.g., strength members).
Seal fiber scraps in puncture-proof containers.
Always refer to GJPFJV datasheet for exact bend radius, tensile limits, and environmental tolerances.
By following these structured steps, you ensure reliable installation and longevity of GJPFJV indoor fiber cables while adhering to safety and performance standards.
GJPFJV indoor optic fiber cables are designed for high-performance, reliable data transmission within building environments. Their construction and compliance with safety standards make them suitable for diverse applications:
Used for horizontal and vertical cabling to connect workstations, servers, and network equipment across floors.
Links telecommunication rooms, ensuring high-speed data transfer between departments.
Facilitates high-bandwidth communication between servers, storage systems, and switches.
Supports dense, high-speed connections in server racks with minimal bend radius.
Integrates with HVAC, lighting, and security systems for centralized control.
Transmits data for smart meters and sensors.
Handles large data volumes from MRI, CT scans, and digital radiography systems.
Ensures reliable connectivity for real-time health data transmission.
Delivers high-resolution video feeds over long distances within buildings, immune to electromagnetic interference.
Connects machinery and control systems in EMI-heavy environments.
Supports real-time data exchange for robotics and PLCs.
Provides high-quality video/audio streaming in hotels, universities, and conference centers.
Links multiple buildings within a campus for unified communication.
Used in wiring closets and distribution frames for last-mile connectivity.
Utilizes Low Smoke Zero Halogen (LSZH) jackets, minimizing toxic fumes and corrosion in case of fire, enhancing occupant safety.
Suitable for installation in air-handling spaces (plenums), meeting stringent fire codes like NEC (National Electrical Code).
Allows for tighter bend radii without signal loss, ideal for routing through walls, ceilings, and tight spaces.
Reduces cable bulk, simplifying handling and installation in cable trays or conduits.
Supports high-speed data transmission for applications like LANs, data centers, and smart buildings.
Ensures minimal signal loss over long intra-building distances.
Unaffected by electromagnetic interference, reliable in environments with electronic equipment.
Resists physical stress, temperature fluctuations, and humidity common in indoor settings.
Reinforced for vertical installations and multi-story routing.
Designed for easy splicing and connector attachment, reducing deployment time and costs.
Facilitates fiber identification and organization in complex networks.
Suitable for offices, hospitals, campuses, and industrial settings.
Works seamlessly with existing network infrastructure and standards.
Free from hazardous substances, aligning with global environmental standards.
Select the fiber type based on the transmission distance requirements.
Multimode fiber is suitable for short distance transmission (such as inside buildings), with relatively low prices, and can meet the high bandwidth data transmission needs.
Single mode fiber is more suitable for long-distance transmission, with a higher price but longer transmission distance and lower signal loss.
Choose the appropriate number of fiber cores according to actual needs. The more cores there are, the larger the amount of data that can be transmitted simultaneously, but the price also increases accordingly.
For general indoor applications, such as connecting multiple devices or requiring high bandwidth, fiber optic cables with more cores can be chosen.
The sheath material has a significant impact on the performance and service life of fiber optic cables. Wear resistant, corrosion-resistant, and flame-retardant sheath materials should be selected to ensure the stability and safety of fiber optic cables during long-term use.
Packaging Details: Packed on drums;
Drums length: 1KM,2KM, 3KM or 4KM, as per buyers'request
Delivery detail: 15 days
