The Era of Fusion Splicing Is Coming

by Fiber-MART.COM

As fiber deployment has become mainstream, splicing has naturally crossed from the outside plant (OSP) world into the enterprise and even the data center environment. Fusion splicing involves the use of localized heat to melt together or fuse the ends of two optical fibers. The preparation process involves removing the protective coating from each fiber, precise cleaving, and inspection of the fiber end-faces. Fusion splicing has been around for several decades, and it’s a trusted method for permanently fusing together the ends of two optical fibers to realize a specific length or to repair a broken fiber link. However, due to the high costs of fusion splicers, it has not been actively used by many people. But these years some improvements in optical technology have been changing this status. Besides, the continued demand for increased bandwidth also spread the application of fusion splicing.

 

New Price of Fusion Splicers

Fusion splicers costs have been one of the biggest obstacles to a broad adoption of fusion splicing. In recent years, significant decreases in splicer prices has accelerated the popularity of fusion splicing. Today’s fusion splicers range in cost from $7,000 to $40,000. The highest-priced units are designed for specialty optical fibers, such as polarization-maintaining fibers used in the production of high-end non-electrical sensors. The lower-end fusion splicers, in the $7,000 to $10,000 range, are primarily single-fiber fixed V-groove type devices. The popular core alignment splicers range between $17,000 and $19,000, well below the $30,000 price of 20 years ago. The prices have dropped dramatically due to more efficient manufacturing, and volume is up because fiber is no longer a voodoo science and more people are working in that arena. Recently, more and more fiber being deployed closer to the customer premise with higher splice-loss budgets, which results in a greater participation of customers who are purchasing lower-end splicers to accomplish their jobs.

 

More Cost-effective Cable Solutions

The first and primary use of splicing in the telecommunications industry is to link fibers together in underground or aerial outside-plant fiber installations. It used to be very common to do fusion splicing at the building entrance to transition from outdoor-rated to indoor-rated cable, because the NEC (National Electrical Code) specifies that outdoor-rated cable can only come 50 feet into a building due to its flame rating. The advent of plenum-rated indoor/outdoor cable has driven that transition splicing to a minimum. But that’s not to say that fusion splicing in the premise isn’t going on.

 

Longer distances in the outside plant could mean that sticking with standard outdoor-rated cable and fusion splicing at the building entrance could be the more economical choice. If it’s a short run between building A and B, it makes sense to use newer indoor/outdoor cable and come right into the crossconnect. However, because indoor/outdoor cables are generally more expensive, if it’s a longer run with lower fiber counts between buildings, it could ultimately be cheaper to buy outdoor-rated cable and fusion splice to transition to indoor-rated cable, even with the additional cost of splice materials and housing.

 

As fiber to the home (FTTH) applications continue to grow around the globe, it is another situation that may call for fusion splicing. If you want to achieve longer distance in a FTTH application, you have to either fusion splice or do an interconnect. However, an interconnect can introduce 0.75dB of loss while the fusion splice is typically less than 0.02dB. Therefore, the easiest way to minimize the amount of loss on a FTTH circuit is to bring the individual fibers from each workstation back to the closet and then splice to a higher-fiber-count cable. This approach also enables centralizing electronics for more efficient port utilization. In FTTH applications, fusion splicing is now being used to install connectors for customer drop cables using new splice-on connector technology and drop cable fusion splicer.

 

FTTH drop cable fusion splicer

 

A Popular Option for Data Centers

A significant increase in the number of applications supported by data centers has resulted in more cables and connections than ever, making available space a foremost concern. As a result, higher-density solutions like MTP/MPO connectors and multi-fiber cables that take up less pathway space than running individual duplex cables become more popular.

 

Since few manufacturers offer field-installable MTP/MPO connectors, many data center managers are selecting either multi-fiber trunk cables with MTP/MPOs factory-terminated on each end, or fusion splicing to pre-terminated MTP/MPO or multi-fiber LC pigtails. When you select trunk cables with connectors on each end, data center managers often specify lengths a little bit longer because they can’t always predict exact distances between equipment and they don’t want to be short. However, they then have to deal with excess slack. When there are thousands of connections, that slack can create a lot of congestion and limit proper air flow and cooling. One alternative is to purchase a multi-fiber pigtail and then splice to a multi-fiber cable.

 

Inside the data center and in the enterprise LAN, 12-fiber MPO connectors provide a convenient method to support higher 40G and 100G bandwidth. Instead of fusing one fiber at a time, another type of fusion splicing which is called ribbon/mass fusion splicing is used. Ribbon/mass fusion splicing can fuse up to all 12 fibers in one ribbon at once, which offers the opportunity to significantly reduce termination labor by up to 75% with only a modest increase in tooling cost. Many of today’s cables with high fiber count involve subunits of 12 fibers each that can be quickly ribbonized. Splicing those fibers individually is very time consuming, however, ribbon/mass fusion splicers splice entire ribbons simultaneously. Ribbon/mass fusion splicer technology has been around for decades and now is available in handheld models.

 

Conclusion

Fusion splicing provides permanent low-loss connections that are performed quickly and easily, which are definite advantages over competing technologies. In addition, current fusion splicers are designed to provide enhanced features and high-quality performance, and be very affordable at the same time. Fiberstore provides various types and uses of fusion splicers with high quality and low price. For more information, please feel free to contact us at sales@fiber-mart.com.

something about optic fiber Splicing

A splice is a device to connect one fiber optic cable to another permanently. It is the attribute of permanence that distinguishes a splice from connectors. Nonetheless, some vendors offer splices that can be disconnected that are not permanent so that they can be disconnected for repairs or rearrangements. The terminology can get confusing.

Fiber optic cables may have to be spliced together for any of a number of reasons. 

One reason is to realize a link of a particular length. The network installer may have in his inventory several fiber optic cables but, none long enough to satisfy the required link length. This may easily arise since cable manufacturers offer cables in limited lengths - usually 1 to 6 km. If a link of 10 km has to be installed this can be done by splicing several together. The installer may then satisfy the distance requirement and not have to buy a new fiber optic cable.

Splices may be required at building entrances, wiring closets, couplers and literally any intermediary point between Transmitter and Receiver. 

At first glance you may think that splicing two fiber optic cables together is like connecting two wires. To the contrary, the requirements for a fiber-optic connection and a wire connection are very different. 

Two copper connectors can be joined by solder or by connectors that have been crimped or soldered to the wires. The purpose is to create an intimate contact between the mated halves in order to have a low resistance path across a junction. On the other hand, connecting two fiber optic cables requires precise alignment of the mated fiber cores or spots in a single-mode fiber optic cable. This is demanded so that nearly all of the light is coupled from one fiber optic cable across a junction to the other fiber optic cable. Actual contact between the fiber optic cables is not even mandatory. The need for precise alignment creates a challenge to a designer of a splice.

There are two principal types of splices: fusion and mechanical.

Fusion splices - uses an electric arc to weld two fiber optic cables together. The splices offer sophisticated, computer controlled alignment of fiber optic cables to achieve losses as low as 0.05 dB. This comes at a high cost.

Mechanical-splices all share common elements. They are easily applied in the field, require little or no tooling and offer losses of about 0.2 dB.

Have You Chosen the Right Fiber Patch Panel?

Have You Chosen the Right Fiber Patch Panel?

by Fiber-MART.COM

Fiber patch panel, namely fiber enclosure, is employed for better cable management and cable protection in data centers. With the help of fiber patch panels, it is more time-saving and easier for technicians to do the cabling work. Fiber patch panel terminates the fiber optic cables and provides access to the cables’ individual fibers for cross connection. In today’s market, there are various types of fiber patch panels. Choosing the right one for your network may seem a little complicated. This article will give several aspects that are important for selecting fiber patch panels.

Some Aspects for Consideration

Loaded vs. Unloaded

Loaded patch panel is pre-installed with adapter panels or cassettes while unloaded patch panel is empty with nothing inside. Typically, LC and MTP connectors are widely used in loaded patch panels. But these connectors in loaded panels are often permanently mounted, so if a port gets damaged it’s dead forever. Unloaded patch panel, on the contrary, is more flexible that can let you swap out defective ports at will. But extra assemblies are demanded to be purchased and installed by yourself.

 

Patch Panel Rack Size

Fiber patch panel is usually measured by rack unit. A rack unit is used to describe the height of electronic equipment designed to mount in a 19-inch wide rack or a 23-inch wide rack. The height of rack-mounted equipment is frequently described as a number with U or RU. 1U refers to one rack unit, 2U refers to two rack units and so on. 2RU and 4RU are often used for high-density installations. So according to your application, the related rack size should also be adjusted.

 

patch-panel-rack-unit

 

Port Density

Port density is also an important part to be considered when purchasing fiber patch panels. As for normal patch panel, 1RU is able to carry 48 ports. If high-density patch panel is required, 1RU can support 96 ports. Moreover, 144 ports in 1RU is also available with ultra density patch panels. Since high-density has been frequently applied to the data centers, patch panels with higher port density becomes the future trend.

 

Migration to High-Density Patch Panels

Nowadays, people are paying more attention to the 40G and 100G high speed networks. MPO/MTP breakout patch panel may be an ideal solution for this high-density installation. Deploying high-density patch panels has many advantages. It simplifies the cabling deployment by running a short fiber patch cable from your SAN or network switch up to the fiber patch panel. Much space can also be saved in data centers by mounting more cables into a smaller space. Installation is easier since no tools are required to install cassettes in the patch panels, and push-pull tabs are used to ease the difficulty of cable connections in the patch panels. After all, high-density patch panel is a cost-effective solution that overcomes the cabling congestion in high bandwidth networking.

 

high-density-fiber-patch-panel

 

Summary

The well-organized and well-protected cables are the guarantee of a stable network. Fiber patch panel is definitely the perfect solution that meets all the requirements. Choosing the right fiber patch panel is also beneficial to your network. You may consider from the aspects of loaded or unloaded types, rack size, port density, etc. In addition, high-density fiber patch panel is welcome by the 40G/100G network. If you want to achieve better high bandwidth application, patch panels with high-density ports are recommended.