Aurora FW 312- Compact Fusion Splicer- Fusion Splicer Supplier-Compact Fusion Splicer Supplier-Aurora FW 312 Compact Fusion Splicer- Aurora FW 312 Fusion Splicer
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Data Supply Is Your One Source For All Your Fiber Optic Fusion Splicers
Part No: FW312
Plenum Innerduct now carries the Aurora FW 312, and is a Compact Fusion Splicer, Fusion Splicer Supplier, Compact Fusion Splicer Supplier, Aurora FW 312 Compact Fusion Splicer, and Aurora FW 312 Fusion Splicer. The
FW312 is a fully automatic arc fusion splicer using advanced LID technology. The
Aurora Automatic Fusion Splicer is microprocessor controlled and built for field
operations in the real world, this splicer is designed to be adaptable to many
situations and to give the installer a fast and accurate result. It comes factory
programmed with six of the most common splice profiles and storage space for fourteen
additional. A crisp 45X magnification view with 25 micron markers makes the fibers
clearly visible before, during and after the splice. The FW312 is user friendly
and is engineered for one button splicing. All fiber types can be spliced, including
multimode, single mode, and specialty fibers. The case contains all tools and
accessories.
Related
Products Attachments
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Fusion Splicer W/ Cleaver
Aurora Automatic Tension Tester
Aurora Standalone
Oven
Aurora Built-In ULTRAsleeve Closing Tool
Aurora Dust Cover
Aurora
Infinitely Variable Tensile Tester
Aurora Built-In Work Light
Aurora Source
Port (850um)
Aurora Source Port (1300um)
Aurora LID for 1300um
Aurora
External Source Current/Voltage Supply
Aurora External Detector Adaptor
Aurora
Rotary Alignment Fixture
Aurora Polarized Source Port (1300nm)
Aurora Polarized
Source Port (1550nm)
Aurora Polarized Pigtail Single Mode Source
Aurora
External Polarized Detector (1300nm)
Aurora Butterfly Splice Crimper Assembly
Aurora
External Video View Screen
Aurora External 12V Battery with Charger
FW312
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3500 Aurora Automatic
Fusion Splicer
2500 Aurora Automatic Fusion Splicer
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3500CDH Aurora
Fusion Fusion Splicer W/ C, D, H
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3000CDH
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3000DH
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2500DH
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TYPICAL USERS/CUSTOMERS
The Altima X is designed primarily for splicing in difficult-to-reach locations and adverse environments. In other words, it is designed to take fully automatic benchtop splicing performance into the field, wherever a user’s hands can reach. Ideally it can be applied either for repair and maintenance or for initial installation.
Key markets would be:
- Fiber to the premises (FTTP)
- military networks and communications systems
- Shipboard repair of fiber cable
- Aircraft
- Tactical fiber systems (tactical communications systems, communications vans, etc.)
- Secure networks and links, particularly with hard-to-access cables
3. STANDARD AND OPTIONAL contentS OF KIT
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ALTIMA X KIT AND OPTIONS |
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as of 16 March, 2004 |
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Actual Size |
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Weight |
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P/N |
Item |
inches |
cm |
pounds |
kg |
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STANDARD KIT |
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Fusion head with fiber holders (pair), clear cover, cable hanger, and hanger screws |
10.4 x 5.8 x 2.8 |
26 x 14.5 x 7 |
4 |
1.8 |
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electronics module with display/keypad module |
7.5 x 5.5 x 3 omitting power cord |
19 x 14 x 7.6 omitting power cord |
2.2 omitting power cord |
1 omitting power cord |
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AC power supply with power cord |
6.3 x 3.8 x 2.5 omitting power cord |
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1.8 omitting power cord |
0.82 omitting power cord |
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battery, small, 4.5 A-hr, with "cigarette lighter" receptacle |
4.0 x 1.75 x 3.0 omitting wire and receptacle |
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1.5 |
0.68 |
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charger for battery pack |
2.3 x 1.8 x 1.6 omitting power cord |
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0.5 |
0.23 |
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remoting cable, head to module |
60 long |
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0.75 |
0.34 |
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remoting cable, module to display |
39 long |
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0.25 |
0.11 |
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fiber buffer coating stripper, Miller 103S |
5.25 x 3.5 x 0.4 |
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0.2 |
0.09 |
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air bulb for blow cleaning |
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K796355 |
User Manual |
11 x 8.5 x 0.4 |
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0.2 |
0.09 |
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alcohol wipes, pack of 10 |
2.6 x 3 x 1 |
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0.1 |
0.05 |
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UltraSleeves, 50 (2 packs of 25 each) |
8 x 3.75 x 0.5 |
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12 VDC extension cord |
120 long |
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Miscellaneous parts in utility box, includes |
9.1 x 4.6 x 1.3 |
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0.8 |
0.36 |
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spare electrodes, 1 pair (2) |
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Allen wrench set |
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cotton swabs, bag |
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Altima X spare screw set |
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screwdriver |
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electrode scrubber |
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tweezers |
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3 Amp fuse |
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SMF test fiber, 1 m |
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Zero "regular" carrying case with cushioning foam |
13 x 21 x 7.5 |
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9 |
4.09 |
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TOTAL BASE KIT |
21 x 13 x 7.5 |
33 x 53.3 x 19 |
21.5 |
9.77 |
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OPTIONS |
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precision fiber cleaver, fixtured for Altima X fiber holders, in box |
2.9 x 2.9 x 2.9 |
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0.75 |
0.34 |
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Fiber holders for 900 micron coatings |
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cleaver hanger |
9.7 x 3.6 x 1.75 |
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0.3 |
0.14 |
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battery belt, large, 7.5 A-hr, with "cigarette lighter" receptacle |
15 x 3 x 1.5 |
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5 |
2.27 |
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heat shrink oven |
5 x 2 x 1.8 |
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5 |
2.27 |
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tripod work tray |
4 x 9 x 1.7 |
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0.6 |
0.27 |
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pocket pc monitor and user interface (replaces LCD display and keypad module) |
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DC extension cord |
120 long |
300 long |
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thermal stripper fixtured for Altima X fiber holders |
6.3 x 2.1 x 1.8 |
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1.6 |
0.73 |
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one-touch automatic precision fiber cleaver |
4.5 x 3.75 x 2.5 |
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1.3 |
0.59 |
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glasses-mountable heads-up display with (2) AAA batteries and cable |
6 x 1 x 1 approximately |
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0.2 |
0.09 |
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high-performance padded carrying and shipping case |
28 x 18 x 14 approximately |
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18 |
8.18 |
4.
END-USER PRICING PER GSA SCHEDULE
The following is a verbatim extract from Aurora Instruments’ GSA schedule price list:
ITEM PRICE ($) SIN
Altima X miniature modular dual mode automatic fusion splicer 28,500 132 8
-In addition to the Altima X fusion splicing system, this kit
also includes all the following minor accessories, spare parts,
and consumables:
4.5 Amp-hour small NiMH battery belt/pack with AC charger
Air bulb for cleaning
Fiber buffer coating stripper
User manual
Alcohol wipes, package of (10)
UltraSleeves, package of (50)
AC power supply with 12 VDC receptacle
AC power cord
Padded carrying case
Maintenance kit with the following items:
Spare electrodes (pair)
Electrode scrubber
Tweezers
screwdriver
Cotton swabs (package)
Allen wrench tool kit
3 amp fuse for dc power cord
Corning SMF28 single mode test fiber
Altima X major accessories and options (not included above)
High precision fiber cleaver, CI-01, fixtured for Altima X 1000.00 132 8
UltraSleeve closing tool (stand-alone) 130.00 132 8
Automatic tension tester 995.00 132 8
LID system converted to 1310 nm operation 1995.00 132 8
7.5 Amp-hour large NiMH battery belt/pack with AC charger 897.00 13
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Fusion Splicing Systems
Plenum Innerduct has prepared this Fusion Splicer Analysis, Fusion Splicer Comparisonand, Fusion Splicer Market, and Fusion Splicer Forecast for you to help evaluate and see where the fiber optic trends my be going. As the name implies, fusion splicers are instruments that make a fusion splice; that is, at the junction where two or more optical fibers are brought together, the fibers are melted together to form a single strand. Optical-fiber cables are joined in this way for any number of reasons: to shorten long cable runs, to economize in crowded conduits, and to meet fire code restrictions, to name a few. Fusion splicing generally uses an electric arc to soften the ends of the two glass fibers, at high temperature, while they are in contact with each other and are being pushed slightly together. When a fusion splice is properly made, the joint is virtually indistinguishable from an uncut fiber.
Sounds easy? There used to be several intangibles that you had to take into account when splicing two optical fibers together. During the primitive stages of modern fusion splicer development no more than eight years ago, a length of stripped fiber would curl a bit along its length when you placed it in a splicing V-groove. This inconvenience was called "fiber curl." Fiber curl adversely affected mass-fusion splice yield because it contributed to splicer offset. Offset causes core misalignment that results in higher splice losses. Offset can also be caused by contaminants such as dirt in the splicer V-grooves and particles or buffer remains on the bare glass.
You and your fusion splicer had to contend with the sun and wind since this is an outside plant (OSP) activity. At times, when using a V-groove to passively align the two fibers, you had to cope with various types of geometrical aberrations in the fibers themselves. Large diameter fibers rise up from the V-groove, while small fibers sink down. Cladding noncircularity, or "ovality" as it was sometimes called, also made it hard for you to align the fiber cores. The joint's loss will depend on the angular orientation of the oval fiber in the groove. Any noncircular fiber or offset diameter will affect the reliability of your splice.
Technical innovations have helped to erase these primitive concerns. Automation, compatible software, and one-step procedures have taken away the element of chance and the capacity for human error. Today's fusion splicers either use fixed V-groove or core alignment systems. "High-end" single-fiber splicers use the core alignment technology, while mass fusion splicers and "mini" (portable) splicers use fixed V-groove.
Fixed V-groove
The fixed V-groove splicer is an economical choice that depends upon quality fiber for high-quality results. When a fixed V-groove splicer is used to estimate splice loss, it operates by assuming that the cladding of the fibers-not the cores-is aligned. Manufacturers have improved fiber quality in recent years so this is not an issue anymore. George O'Mara, production manager, Sumitomo Electric Lighwave (www.sel-rtp.com), told how "fiber curl" is no longer a problem, even with ribbon fiber. "We are in a fortunate position to have some new technology to manage with the V-groove and to look at our ribbon closely to make sure it is what we need to do the splicing." Sumitomo's Type-65 Micro-Mass fusion splicer uses this fixed V-groove alignment system and features a 5.6-inch display to give you a clear fiber image even in direct sunlight.
The fiber viewing system provides simultaneous focusing of up to 12 fibers at a time and maintains equal resolution across all fibers for improved accuracy of splice loss estimations. Also, the high-speed, high-resolution image processing system automatically evaluates the fibers in two planes (X and Y axis) for cleave end-face quality, cleave length irregularity, and fiber offset to screen out most likely causes in high-loss splices. With battery operation, wind protection, and a compact size, the Type-65 is designed for aerial and taut-sheath applications. This wind protective design lets you splice in winds of up to 30 mph.
Fitel Technologies' (www.fiteltech.com) S199S is an example of how you can splice in the field for longer periods of time without worrying about running out of power. On average, it takes a longer amount of time to splice using fixed V-groove technology as opposed to core-to-core alignment. The S199S has a battery capacity indicator that gives you an indication of how much longer you can operate in the field before you have to recharge. "A slide-in battery in the S199S as well as in Fitel's core-aligning S176 makes the fusion splicers more portable," says Darren Newman, service engineer at Fitel's technical center. Either an AC/DC converter or battery can be slotted in the main body of the S199S without wiring.
Corning Cable Systems' (www.corn ing.cablesystems.com) MiniMASS Series 5000 fixed V-groove fusion splicer offers an uninterruptible power supply. You can either operate on AC, DC, or battery power with the MiniMASS Series 5000. Once either source of power runs out, the other will automatically take its place. "If you are in the process of splicing and the AC power goes, it will not stop the process," explains Jeff Fullwood, product line specialist for splice equipment. "This makes sure there is no 'hiccup' in your performance." Also, a "snap-in" magnetic handler feature is designed for consistent placement into the V-groove. These handlers are made of a high-density polymer material. At the bottom side of the handler, there is a small metal plate. When you place the handler in the stage of the splicer, a magnet pulls the handler and the fiber into the groove. This feature lets you place the fibers to be spliced into the unit without having to physically touch the fibers and risk contamination.
Profile alignment system
A fusion splicer using a profile alignment system images fibers and measures the important geometrical parameters of each cable. By viewing the fibers from two perpendicular directions, the images are computer-processed and analyzed to determine cladding offset, core deformation, variation in fiber outer diameters, and other relevant parameters. These measurements are used in an algorithm to estimate a splice loss.
AFL Telecommunications Fujikura Ltd. (www.aflfiber.com) offers an FSM-40S fusion splicer that uses PAS core alignment technology. This type of splicer is designed to optimize the alignment of the fiber before splicing to get the lowest possible splice loss. The FSM-40S features a selectable image display that includes single- and dual-axis fiber viewing on a 5-inch LCD monitor. Instead of evaluating the fiber in two planes (X and Y axis), such as with fixed V-groove technology, PAS measures alignment on three planes (X, Y, and Z axis).
This automated method of fusion splicing requires several moving parts to measure alignment on three planes, and generates a tremendous amount of heat. For this reason, the FSM-40S features automatic temperature and humidity compensation. It can withstand extreme environments and means you can create an accurate core-to-core splice in any OSP project.
"An internal pressure and temperature gauge continuously monitors the atmospheric surroundings around the splicer," explains Vitas Laniauskas, product specialist (OFSP), AFL Telecommunications Fujikura Ltd. "In certain situations, the gauge will alert the operator, or will make changes, or 'keep tabs' on changes when an arc calibration takes place." A feature that compensates for environmental conditions makes the FSM-40S a solution for aerial taut-sheath applications. Aerial taut-sheath splicing involves cross winds, and at times, harsh outdoor conditions. Also, the small footprint of the FSM-40S makes the unit portable, and it "won't get in your way" during aerial taut-sheath splicing, according to Laniauskas. This is useful since you work with a limited workspace for this application.
In addition to having a smaller footprint, core-to-core fusion splicers such as the FSM-40S have multiple pre-programmed modes for specialized splicing. Core-to-core fusion splicers are designed to fuse singlemode, multimode, non-zero dispersion-shifted (NZ-DS), dispersion-shifted (DS), cutoff-shifted (CS), and erbium-doped fiber. These different types of fiber will have different dimensions, as well as other individual characteristics such as fiber quality or age.
Local-injection detection alignment
Local-injection detection (LID) alignment is similar to PAS in that it fuses fibers core-to-core and has the ability to splice two fibers with dissimilar characteristics. This technology also aligns the X, Y, and Z axes for a precise splice. In LID alignment, the machine injects light into the core of one fiber and detects the amount of light in the other fiber.
Corning Cable Systems' Series 7000 X77 is an example of a fusion splicer that uses LID alignment. The unit injects a 1,300-nm light signal directly into the core of the fiber, moves the fibers in three axes for alignment purposes, and then monitors that light signal during fusion. An Automatic Fuse Time Control (AFC) feature in the X77 lets you monitor the LID levels in real-time. By actively monitoring the LID levels during fusion, you can compensate for varying environmental changes and splice wear.Aurora Instruments (www.aurora-instruments.com) offers a Source port option for its FW312 fusion splicer that lets you work with bare or dark-color-coated fibers. This Source port directs the source current away from the standard LID injector to the source port. The feature allows automatic LID-optimized splicing of fibers with any coating or jacket, regardless of thickness or color.
PAS/LID combination
Aurora Instruments Inc. uses a combination of PAS and LID alignment systems in its Fusion 3500. Sub-pixel image processing in both X and Y axes simultaneously lets you get an alignment, slice, and splice loss estimate in addition to giving the operator a clear view of the operation.
When aligning fibers core-to-core, it is important to be able to monitor the splice and check for remaining particles or buffer remains. Data points are normally recognized as pixels on a monitor. Sub-pixel image rocessing lets you see between pixels. "Sub-pixel resolution is a software method that scans across an image and builds a function of light intensity versus pixel position and it can interpolate between the [data] points," says Larry Wesson, president, Aurora Instruments. This feature lets you view the geometrical parameters of the fibers from two perpendicular directions to use the PAS alignment method. In addition, the ability to measure light intensity complements the LID mode. The sub-pixel resolution will enhance your view of the light so that you may align the cores with improved accuracy.
Looking to the future
Fusion splicer manufacturers are moving towards units with a smaller footprint, more programmable features, automation, versatility, and ruggedness. Improvements in fiber manufacturing are reducing quality concerns, and technology finds new ways to help you.Ryan Cliche is Assistant Editor for Cabling Installation & Maintenance.
The worldwide consumption value of fiber optic fusion splicers will double from $233 million in 2002 to $471 million in 2007 according to study results just-released by ElectroniCast Corp. "The Japan/Pacific Rim region will eventually take the market share lead," said Stephen Montgomery, president of the market forecast consultancy. "There are several application standouts throughout the 2002-2012 forecast period, especially the use of fusion splicers by manufacturers of fiber optic components/products in Asia," Montgomery said.
The Fiber Optic Fusion Splicer Global Market Forecast presents the dollar value, quantity, and average price for various "single-fiber" and "multifiber" splicer products. ElectroniCast's study examines the relative material, capital and labor costs of mechanical versus fusion splices, the trends in cable installation and midspan access techniques and the preferences of cable installers, to derive a ten year forecast of the relative quantity share of total splices served by each method. This analysis leverages from ElectroniCast's fiber optic cable forecast, which details the total fiber quantity and the share held by single loose tube, multiple loose tubes, ribbon and tightly buffered cables.
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