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Fusion Splicing Basics (Part 1): Fiber Alignment

This blog is the first in a series that will overview fusion splicing equipment and methods, particularly those of interest to the cable/broadband industry. Information to support this series was sourced from Fusion Splicing Equipment and Applications for the Cable/Broadband Industry (SCTE 134 2021) — an SCTE Standard authored by UCL Swift Fiber Optic Engineer Rich Case. When it comes to ensuring that your fiber network can provide superior performance, utilizing fusion splicing offers many distinct advantages over mechanical splicing. Fusion splicing consists of aligning and permanently fusing stripped, cleaned and cleaved optical fibers with a high-temperature arc.Mechanical splicing utilizes an alignment device and index-matching gel with a similar refractive index and covers the possible air gaps, helping light travel from one fiber to another. Because mechanical splicing simply “holds” the spliced fiber ends together, the typical insertion loss can be higher than a fusion splice which provides a continuous connection between two fibers.From splice-on connectors to pigtails or installation and repair for direct cable-to-cable splicing, fusion splicing provides overall better performance and better protection from signal failure. As mentioned, fusion splice losses are typically lower and are not subject to the environmental limitations of mechanical splices. They provide a fast, reliable, low-loss connection with the lowest loss (in the range of 0.01 dB to 0.10 dB for single-mode fibers) and are practically non-reflective. While fusion splicing does offer the most benefits for performance, their ability to provide this performance in a variety of environmental settings is what makes them so versatile and a must-have for fiber network installs.Fusion splicers are typically used in the field or within a Lab/OEM environment. While you may use many splicers in either environment, some splicers are designed for specific performance environments. Two fiber alignment techniques are:- Passive Alignment (Single-axis)- Active Alignment (Multi-axis)  Passive Fiber AlignmentPassive alignment systems do not move the fibers in the x or y axes but move the fibers in the z-axis only (single-axis).You should use this technique in fixed v-groove machines.Fiber alignment is dependent on how the fibers are positioned relative to each other in the precision-cut grooves in the x and y axes. To achieve a good quality splice, you must align the two fiber ends correctly.The cleanliness and good condition of the v-grooves are essential to ensure that the fibers are positioned in the v-groove to allow the proper alignment necessary for a good quality splice. Active Fiber AlignmentActive alignment systems detect and compensate for any fiber misalignment, moving the fibers in the x, y and z axes (multi-axis). Active alignment methods fall within one of the following categories: 1. Local Injection and Detection (LID) SystemThe LID system aligns and monitors the fusion splice with an optical transmitter and receiver. It allows for the cores to be optimally aligned. A source (transmitter) injects a light signal into the fiber through a bending coupler, and a power meter (receiver) measures the received light signal through another coupler. When the transmitted signal is at its maximum level, both fiber cores are perfectly aligned.The transmitted signal from the LID source is present throughout the process, allowing effective control of the splicing process. The LIDTM system provides a splice loss measurement after the splice is complete by comparing the post-splice light level to the pre-splice level.2. Core Detection System (CDS)Another active alignment method, the CDS, uses the luminescence properties of optical glass. The core and the cladding of optical fiber have different optical properties. For example, the fiber core glows brighter than the cladding when an arc is applied to the fiber due to its different doping. To detect the core, a short arc fires, allowing the core-cladding-contrast to be detected.3. Lens-Profile Alignment System (L-PAS)With an L-PAS method, an optical system consisting of cameras, lenses, prisms, and LEDs makes the fiber visible. The fiber image is generated by a backlit arrangement, using LEDs that shine through prisms that project the fiber’s shadow through lenses onto a camera. Analyze the fiber alignment by comparing the positions of the two fibers. The system “sees” mainly the cladding, producing alignment using the relative cladding diameters.4. Profile Alignment System (PAS)The PAS works on the same principle as the L-PAS system, except that in addition to “seeing” an image of the cladding, focus lenses also allow an image of the core to be detected.  5. Fiber Splicer ConsiderationsWhen choosing the right fusion splicer for a particular application, it is crucial to take into consideration some of the following aspects: Loss Requirements : Determine the loss requirement of the application. Active core alignment splicers provide more precise and lower loss results than passive alignment systemsValue : In general active alignment units are more expensive; however, they typically provide lower splice loss and can be used wherever a passive alignment unit can. It is essential to determine what application you will most often use and match those needs to the correct fusion splicer.Features and Ease of Use : These are necessary to consider when choosing your splicer. They increase productivity and allow various skill levels of personnel to use the machine. Combination-style splicers combine multiple tools within a single chassis versus standard splicers grouped with other tools such as strippers and cleavers.Alignment Methods : Splicing 250 um fiber and 200 um fiber leads to challenges of adequately holding and aligning the fiber. Using the correct fiber equipment holders and clamps will allow the fiber to be captured and presented in the V-grooves.

Jan 21, 2024

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Fusion Splicing Basics (Part 2): Strippers and Cleavers

This blog is the second in a series that will overview fusion splicing equipment and methods, particularly those of interest to the cable/broadband industry. Information to support this series was sourced from Fusion Splicing Equipment and Applications for the Cable/Broadband Industry (SCTE 134 2021) — an SCTE Standard authored by UCL Swift Fiber Optic Engineer Rich Case.When performing a fusion splice, the optical fiber must be stripped down to the bare glass. Various techniques can remove the coating:- Mechanical Stripping - Thermal Stripping- Chemical Stripping- Arc StrippingCoating StrippersRegardless of the method used to strip the coating, it is important to use the correct tools and techniques to prevent damage to the bare glass. Ensuring the fiber is not damaged is critical to creating a low-loss, strong splice.  Mechanical StrippingWith mechanical stripping, the coating is removed using a tool that physically “shaves” the coating off. This may be accomplished by machining the tool with a precise profile to match the fiber itself. Advantages are that it is fast and inexpensive, usually found in various hand tools (typically used for single-fiber applications). Disadvantages include reliance on skilled operator technique and potential for scratching the glass due to physical contact with the tool surfaces. Thermal StrippingThermal stripping uses heat to soften the coating before removal. Heating the coating allows much easier removal and lessens the possibility of physical damage to the glass itself. Thermal stripping can be used with single-fiber splicing but is typically used with multi-fiber splicing since it simultaneously strips up to twelve fibers. Thermal stripping is usually more of an automatic process (the equipment does most of the work) and is more friendly to a novice operator. Mechanical Stripper (left) vs. Thermal Stripper (right) Chemical StrippingChemical stripping uses the application of a chemical to soften the coating, possibly causing it to blister. This allows the material to be wiped away and removed. Care must be taken so that the chemicals used are not harmful to the glass or the operator applying them. Arc StrippingArc stripping removes the coating using a high-temperature arc plasma, similar to the arc generated during the splicing operation. Care must be taken to avoid thermal shock to the fiber during the stripping process. CleaversTo achieve good splice results, it is vital for the fiber ends to be properly cleaved. Consistent, good-quality end faces can only be achieved if the cleaver is well-maintained. Cleave angle deviations or chips and knicks in the end-face can only be compensated for by using unusually high fiber feed during the fusion process. This can create a splice with an outer cladding that may look good, but the actual loss could be increased due to core bending. For best results, the smaller the core (i.e., single-mode fiber), the lower the tolerance of cleave angle deviation.  Various cleavers are available that operate in different ways, but the general principles for cleaving the fiber are:Score – A score is introduced into the glass.Bend – The glass is bent to propagate the score.Tension – Tension is applied to separate glass. Types of CleaversSingle-fiber cleavers are designed to cleave one fiber at a time and provide a high-quality end-face angle that leads to low-loss splices. Most multi-fiber cleavers can cleave multiple or single fibers. In many instances, a different handler or adapter may be necessary to accommodate single fiber cleaving.ConsiderationsIt is important to consider several aspects when choosing a cleaver for a particular application as with fusion splicers.Performance – A good cleave is essential to obtain good low-loss splices.Usability – Ease of use is important for users and in obtaining consistent, high-quality results.Quality of Cleave – To obtain quality cleaves from a cleaver, keep these things in mind: 1. Both the fiber and cleaver must be clean.2. The blade must be kept and maintained in good condition. Many systems now use an auto-rotation blade to extend blade life or onboard monitoring to track lifetime performance and notify the operator that a blade change is necessary.3. The proper operating technique must be followed.  Splice ProtectionAfter the fibers have been successfully spliced together, it is important to protect the joint. There are various options for splice protection. One of the most common techniques is a heat shrink sleeve. This sleeve is placed over the fiber before splicing and placed away from the splice point during preparation and fusing.After the splice is complete, the heat shrink is placed over the splice point. It is then placed in a heat-shrink oven, where the material is heated and shrunk down over the fiber, protecting the joint. Clamshell-type protectors are also available. These protectors commonly have a hinged joint that allows it to be placed on the splice point after completing the splice. Most versions use adhesive to hold the fiber in a groove while the other half of the “clamshell” is closed on the fiber that is holding and protecting the joint. 

Jan 21, 2024