Fujikura 90S Fusion Splicer with Bluetooth and CT50 Cleaver
Fujikura 90S Fusion Splicer with Bluetooth and CT50 Cleaver
BY Fujikura
SKU: SKU: NPNB-S017521
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Fujikura 90S+ Core Alignment Fusion Splicer with Bluetooth and CT50 Cleaver
The Fujikura 90S+ Core Alignment Fusion Splicer solves common problems seen in the field. Everything from splicing poor quality legacy fibre to automated equipment maintenance and upkeep. The Fujikura 90S+ can be used in multiple field splicing applications including bend-insensitive fiber in drop cables, long-haul terrestrial and submarine LEAF® fibers, loose buffer fiber, splice-on connectors, and the list goes on.
The speed and accuracy of the 90S+ make it suitable for certain production and specialty environments where high output, tight packaging, and low loss requirements are required.
Regardless of your scenario, the Fujikura 90S+ is designed to keep you in the field with an extended battery life of 300 splice and heat cycles. With its multiple automated and easy-to-use features, the 90S+ alleviates the need for traditional operation tasks such as frequent arc calibrations, cleaver blade rotations, cleaver usage tracking, and manual splicing operations.
A redesigned work tray, cooling tray, and optional cable clamp make the 90S+ kit more versatile than its predecessors in adapting to varying work conditions and environments. When splicing loose buffer fibre, additional sheath clamps are not needed. The standard universal sheath clamp now handles both loose and tight buffer fiber.
The new Active Fusion Control (AFC) technology improves splice losses for fiber with a poor cleave angle. Combined with Active Blade Management between the splicer and cleaver, the Fujikura 90S+ contains a robust set of splicing features that will reduce the likelihood of poor splice installations or repairs.
Features
- Cleaver tracking and upkeep with wireless communication
- Improved real-time arc control for fibers with poor cleave angles
- Loose and tight buffer with same sheath clamp
- Automated wind protector, sheath clamps and splice operation
- Graphical User Interface with 5.0" touchscreen PC software and 90S manual downloaded from splicer
- Multi-function transit case with integrated workstation
- Lithium-ion battery with 300 splices/shrinks per charge
Specifications
| FIBER ALIGNMENT | |
|---|---|
| Fiber Alignment Method | Active core alignment |
| Fiber Count Can Be Spliced | Single fiber |
| APPLICABLE FIBER | |
| Fiber Type | Single-mode optical fiber, Multimode optical fiber |
| Cladding Diameter | 80 to 150 μm |
| APPLICABLE COATING | |
| Sheath Clamp | Coating dia.: Max. 3,000 μm Cleave length: 5 to 16 mm |
| FIBER SPLICE PERFORMANCE | |
| Splice Loss | ITU-T G.652: Avg. 0.02 dB ITU-T G.651: Avg. 0.01 dB ITU-T G.653: Avg. 0.04 dB ITU-T G.654: Avg. 0.04 dB ITU-T G.655: Avg. 0.04 dB ITU-T G.657: Avg. 0.02 dB |
| Splice Time | SM FAST mode: Avg. 8 to 10 sec. SM AUTO mode: Avg. 11 to 13 sec. AUTO mode: Avg. 14 to 16 sec. |
| APPLICABLE PROTECTION SLEEVE | |
| Sleeve Type | Heat-shrinkable sleeve |
| Sleeve Length | Max. 66 mm |
| Sleeve Dia. | Max. 6.0 mm before shrinking |
| SLEEVE HEAT PERFORMANCE | |
| Heat Time | 60 mm slim mode: Avg. 9 to 10 sec. 60 mm mode: Avg. 13 to 15 sec. |
| OTHER PERFORMANCE | |
| Fiber Tensile Test Force | Approx. 2.0 N |
| Electrode Life | Approx. 5,000 splices |
| PHYSICAL DESCRIPTION | |
| Dimensions W | Approx. 170 mm (without projection) |
| Dimensions D | Approx. 173 mm (without projection) |
| Dimensions H | Approx. 150 mm (without projection) |
| Weight | Approx. 2.8 kg (including battery) |
| ENVIRONMENTAL CONDITION | |
| Temperature | Operate: -10 to 50°C Storage: -40 to 80°C |
| Humidity | Operate: 0 to 95% RH non-condensing Storage: 0 to 95% RH non-condensing |
| Altitude | Max. 5,000 m |
| AC ADAPTOR | |
| Input | AC 100 to 240 V, 50/60 Hz, Max. 1.5 A |
| BATTERY PACK | |
| Type | Rechargeable Lithium Ion |
| Output | Approx. DC 14.4 V / 6,380 mAh |
| Capacity | Approx. 300 splice and heat cycles |
| Temperature | Recharge: 0 to 30°C Storage: -20 to 30°C |
| Battery Life | Approx. 500 recharge cycles |
| Recharge Time | Approx. 5-8 hours from empty |
| DISPLAY | |
| LCD Monitor | TFT 5 inches with touch screen |
| Magnification | 200 to 320x |
| Illumination V-Grooves | LED lamp |
| INTERFACE | |
| PC | USB 2.0 Mini B type |
| External LED Lamp | USB 2.0 A type, Approx. DC 5 V, 500 mA |
| Ribbon Stripper | Mini DIN 6 pin, DC 12 V, Max. 1 A |
| Wireless | Bluetooth 4.1 LE |
| DATA STORAGE | |
| Splice Mode | 100 splice modes |
| Heat Mode | 30 heat modes |
| Splice Result | 20,000 splices |
| Splice Image | 100 images |
| OTHER FEATURES | |
| Screw Hole for Tripod | 1/4-20 UNC |
| Automatic Functions | Splice mode select by fiber type analysis Discharge power calibration Wind protector: open/close Sheath clamp: open Heater lid: open/close Heater clamp: open/close |
| Reference Guide | Video and PDF file stored in splicer |
| Sheath Clamp | Easy sleeve positioning clamp |
| Electrode | Replaceable without tool |
Additional Information
Fusion Splicing Process
The process of fusion splicing normally involves using localized heat to melt or fuse the ends of two optical fibers together. The splicing process begins by preparing each fiber end for fusion.
Stripping the Fiber
Stripping is the act of removing the protective polymer coating around optical fiber in preparation for fusion splicing. The splicing process begins by preparing both fiber ends for fusion, which requires that all protective coating is removed or stripped from the ends of each fiber. Fiber optical stripping can be carried out by a special thermal fiber stripper tool that uses hot sulphuric acid or a controlled flow of hot air to remove the coating. There are also mechanical fiber strippers used for stripping fiber which are similar to copper wire strippers. Fiber optical stripping and preparation equipment used in fusion splicing is commercially available through a small number of specialized companies, which usually also designs machines used for fiber optical re-coating.
Cleaning the Fiber
The bare fibers are cleaned using alcohol and wipes.
Cleaving the Fiber
A fiber cleaver is then used to cleave the fiber using the score-and-break method so that its end-face is perfectly flat and perpendicular to the axis of the fiber. The quality of each fiber end is inspected using a microscope. In fusion splicing, splice loss is a direct function of the angles and quality of the two fiber-end faces. The closer to 90 degrees the cleave angle is the lower optical loss the splice will yield.
Splicing the Fibers
Current fusion splicers are either core or cladding alignment. Using one of these methods the two cleaved fibers are automatically aligned by the fusion splicer in the x,y,z plane, then are fused together. Prior to removing the spliced fiber from the fusion splicer, a proof-test performed to ensure that the splice is strong enough to survive handling, packaging and extended use. The bare fiber area is protected either by re-coating or with a splice protector. A splice protector is a heat shrinkable tube with a strength membrane.
What's In The Box
Main Components
- Qty 1 – Fujikura 90S+ Fusion Splicer (with Bluetooth)
- Qty 1 – CT50 Cleaver
- Qty 1 – CC39 Transit Case with Carrying Strap
Power & Accessories
- Qty 1 – ADC-20 AC Adapter
- Qty 1 – ACC-14 AC Cord
- Qty 1 – BTR-15 Battery
Fiber Tools & Consumables
- Qty 1 – ELCT2-16B Spare Electrodes (Pair)
- Qty 1 – Sheath Clamps Set
- Qty 1 – SP-03 Fiber Holder Set Plates
- Qty 1 – SS03 Single Fiber Stripper
Miscellaneous
- Qty 1 – USB-01 Cable
- Qty 1 – Alcohol Dispenser
- Qty 1 – Splicer Carrying Strap
- Qty 1 – Quick Reference Guide
- Qty 1 – Work Tray J-Plate
