Field Installable Optical Connector for Cables



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Field Installable Optical Connector for Cables Daigo Saito 1, Kazuhiro Takizawa 1, Kazuya Ogata 1, and Tan Khee Yen Serin 2 With the rapid expansion of fiber to the home (FTTH) in Japan, mechanical splices and fieldinstallable optical connectors have become important components widely deployed in a FTTH network. To date, we have developed and commercialized these components for various fi bers as well as drop cables. Applying this technology and expertise, we have developed a new fieldinstallable optical connector for cables. This connector exhibits excellent optical characteristics and reliability tests results. We have designed a low cost jig also to improve the ease of installation. 1. Introduction Today filed-installable optical connectors that can terminate optical fibers are widely and successfully deployed in private enterprise networks and Asian FTTx markets 1). Such a connector, which typically incorporates a mechanical splice in its body, has come a long way. Major technological advancements have been made to achieve its present-day characteristics and reliability comparable to its factory assembled counterpart. Ease and reliability of installation are critical factors when it comes to the design and development of field installable techniques. We have reported on mechanical splices and filed-installable optical connectors for optical fibers fulfilling objectives of simple, one-action termination without requirement of polishing ferrule or epoxy curing of fiber in the field 2)-6). However, when it comes to terminate Aramid yarn reinforced optical fiber cables; traditional technique of capturing Aramid yarn proves tedious in the field and also requires certain amount of skills on the installer s part. In accordance with the consideration of easy installation, we have developed a field installable LC connector capable of terminating Aramid yarn reinforced optical cables, with a unique way of securing Aramid yarn, which is less complicated than conventional method and yet maintains the same mechanical strength performance. This paper first examines the structure of this newly developed connector and the improvements made in current technologies, and then describes the termination method. In the end, the characteristics and performance are discussed. 2. Connector structure Figure 1 shows the components of field-installable LC connector for Aramid yarn reinforced cables, 1 Fiber Optics Network Products R&D Department 2 Fujikura Technology Singapore Pte Ltd. whose connector interface is compliant with TIA/EIA 64-1A Fiber Optic Connector Intermateability Standard - Type LC. The composition is similar to existing commercialized field-installable LC connector for fibers (Fig. 2) 7), consisting of a connector plug pre-set with a disposable wedge unit and a boot unit. This filed-installable optical connector is capable of terminating both φ2 mm and φ3 mm cables. The cross-sectional structure of the terminated LC connector is illustrated in Fig. 3. Universal with all our filed-installable optical connectors, the connector body comprises of a mechanical splice unit. The mechanical splice unit is engaged by the wedge unit during field termination of optical cable. The boot unit is equipped with a screw feature to secure Aramid yarn to the back of the connector plug (Fig. 4). It consists of a tube also to provide relief to any strain that might be present as a result of the side pull loads. A jacket clamp is posi- Connector plug with pre-set wedge unit Screw Boot unit Boot Tube Clamp Screw Connector plug Fig. 1. Structure overview of field installable connector for cable. 16

Wedge unit Boot tioned at the end of the strain relief tube to fix cable jacket in position. Conventional approach of fixing Aramid yarn is by means of crimping the Aramid yarn to the back of connector plug via a crimp ring (Fig. 5). This method has the advantage of demonstrating good cable retention strength of more than 5 kgf. However, application of this method in the field can demand the installer as it requires a degree of dexterity and is time consuming. This is further discussed in section 3.3. The screw feature of the boot unit of the new fieldinstallable LC connector for cables has been developed specially to meet the ruggedness exhibited by the predominant crimping technique. The same cable retention strength of more than 5 kgf is realized. 3. Termination process Connector main body Fig. 2. Structure overview of field installable LC connector. 3.1. Assembly tool The assembly tool for the cable developed to improve ease of installation is shown in Fig. 6 and 7. This Cap Bare fiber clamp Clamp spring Coating clamp Spring Kevlar Boot Unit Strain relief tube Pre-installed fiber Wedge Ferrule Index Housing matching gel V-groove plate Screw attachment Strain relief boot Installing cable Jacket clamp Cross sectional view Fig. 3. Cross section structure of connector. Tube Clamp Screw Boot Fig. 4. Structure of boot unit. Fujikura Technical Review, 29 17

Clamp ring After clamping Clamp tool Fig. 5. Current method for clamping. 3.Aramid yarn hook 2.Cable grip 1.Connector plug setting hole Fig. 7. Feature of new assembly jig. part of installing fiber cable to maintain cable bend and therefore fiber contact with pre-installed fiber during fiber termination, which is outlined in section 3.2. The 2 Aramid yarn hooks are used for lightly and evenly fixing Aramid yarn s position on both sides of the connector prior to securing to the back of the connector plug, which is explained in section 3.3. Fig. 6. Overview of new assembly jig. low cost tool comprises of 3 features that simplify the termination process. Connector plug is able to be set onto the assembly tool. Therefore, handling in assembling process in the field becomes easier than the conventional method. The cable grip is used to hold cable 3.2. Termination of cable The process of terminating optical cable with the field-installable LC connector for cables is akin to that of the field-installable LC connector for fibers. Figure 8 illustrates the installation process of optical cable using the assembly tool for cables. Connector plug is set onto the assembly tool and installing cable is prepared and inserted into the connector. A slight resistance is felt while inserting cable contacts pre-installed fiber stub. Form a slight bend in the cable and set cable onto the cable grip to maintain the contact force. Squeeze both sides of the wedge unit to disengage 18

1. Insert prepared cable until contact is felt. 5. Secure boot unit onto back of connector. 2. Make a bend in the cable to maintain connection. 3. Disengage wedges to complete termination. 6. Remove connector from tool and wedge unit and trim Kevlar. 4. Split Kevlar evenly and hook onto both side of tool. 7. Fastening of cable jacket to tube of boot unit. Fig.8. Operation procedure. wedge and grip fiber in the mechanical splice unit of the connector plug. The process completes the termination of cable. Push Tube Fig. 9. Fastening of cable jacket to tube of boot unit. 3.3. Securing of Aramid yarn and cable jacket Securing Aramid yarn by the established method of crimping with a crimp ring has always been a cause of distress, especially for installers, new to the job and yet adept at this skill dependent operation. Figure 8 illustrates also the process of securing Aramid yarn by the screw method, making use of the assembly tool for cable. Aramid yarn is first split into two equal amounts and lightly hooked around the two hooks on the assembly tool. The exposed φ9 μm fiber is then aligned with the Aramid yarn and boot unit is screwed onto the connector plug to secure Aramid yarn tightly. Next, the connector plug is removed from the assembly tool after which the wedge unit is detached and Aramid yarn is trimmed. In contrast, in the crimping approach (Fig. 5), the installer has to slide a crimp ring over the Aramid yarn and the back of the connector, and use a crimp tool to bind the Aramid yarn to the connector. The process of using a crimp tool requires more handiness than the screw mechanism, which can be easily handled by both an experienced installer and a novice. In order to quantify the time required to terminate an Aramid yarn reinforced cord with a field-installable LC connector by both conventional crimping method and new method of using a screw, a technician familiar with field-installation techniques was selected, trained, and put through the actual test with the time taken recorded. The time demanded of him to complete a termination with the crimping method was 6.14 min, while the time necessary to execute a termination with the new method was 3.89 min. This demonstrated that not only was the newly developed method of securing Aramid yarn simpler; but also was it less time consuming which improved efficiency in the field. Finally, as the cable jacket is still unrestrained and there is a likelihood that it may piston out from the boot, thus compromising on the mechanical performance of the connector. To resolve this, a jacket clamp is designed and attached to the end of the tube, to fasten cable jacket to the tube. The force of the clamp is optimally designed such that it is strong enough to hold onto the cable jacket and yet not able to overcome the strength of the mechanical splice unit. Figure 9 shows the operation of this jacket clamp. It is a straightforward step of pushing to engage the jacket clamp and fix cable jacket in place. 4. Characteristics Jacket clamp The field-installable LC connector for optical cable Fujikura Technical Review, 29 19

was designed to exhibit comparable characteristics to factory assembled LC jumper patchcords. The optical performance of the field-installable LC connector is compliant with Telcordia GR-326-CORE. Figures 1 and 11 give the insertion loss and reflectance of the field-installable LC connectors respectively, when terminated with 2 mm single-mode optical cables. Measurements were carried out at wavelengths of 131 nm and 155 nm. The average insertion loss is.22 db at 131 nm and.2 db at 155 nm. The maximum insertion loss is.39 db at 131 nm and.4 db at 155 nm. The mean reflectance is 51.7 db at 131 nm and 49.8 db at 155 nm. The minimum reflectance is 43.1 db at 131 nm and 44.5 db at 155 nm. These results verified that the optical performance of field installable LC connector for cables corresponds to that of the fiber. Environmental and mechanical reliability of the field-installable LC connector have been evaluated. Tables 1 and 2 present the compiled results for all the environmental and mechanical tests, respectively. The thermal cycle test result is shown in Fig. 12. From the results shown, the maximum change in insertion loss for all tests does not exceed.1 db and the mean reflectance is more than 5 db. It is established that field-installable LC connectors for Aramid yarn reinforced cables exhibit consistent and reliable environmental and mechanical performances. frequency 3 25 2 15 1 5 N=1 1.31 μm 1.55 μm Ave. Max..22dB.39dB.2dB.4dB.5.1.15.2.25.3.35.4.45.5 insertion loss (db) Fig.1. Insertion loss. 1.55 μm 1.31 μm 5. SC interface type Figure 13 shows the overview of SC interface type Table 1. Environmental characteristics of field installable LC connector terminated with φ2.mm Kevlar reinforced cable. Test item Thermal age test Low temperature Thermal cycle Humidity / Condensation cycling test Salt mist Condition 85 C, uncontrolled humidity, 168 h PVC fiber: 4 C, 24 h 4 C ~ 75 C, uncontrolled humidity, 21 cycles, 168 h 1 C ~ 65 C, 9 % ~ 1 %RH, 14 cycles, 168 h 35 C, 5 wt%, 24 h Max increase in loss (db) Mean reflectance (db) 1.31 μm 1.55 μm 1.31 μm 1.55 μm.6.9 53.2 55.6.8.1 52.5 53.7.5.7 51.6 52.9.7.7 52.6 53.4.7.3 54.9 52.8 Table 2. Mechanical characteristics of field installable LC connector terminated with φ2.mm Kevlar reinforced cable. Test item Twist test Condition 1.35 kgf,, 9,, -9,, 9 times Max increase in loss (db) Mean reflectance (db) 1.31 μm 1.55 μm 1.31 μm 1.55 μm.8.9 54.1 53.2 Straight pull 3 kgf, 1 min.1.9 55.3 52.9 Flex test Impact test.5 kgf,, 9,, -9,, 1 cycles Concrete block, 1.5m, horionzal position, 8 impacts.8.6 52.1 53.6.1.2 53.2 51.8 Drop test 1.5 m, 5 drops.8.6 52.8 54.3 Durability 5 times.6.3 52.7 53.3 frequency 6 5 4 3 2 1 Ave. Min. reflectance (db) 51.7dB 43.1dB 1.55 μm 1.31 μm N=1 1.31 μm 1.55 μm 49.8dB 44.5dB 4 45 5 55 6 65 7 Fig.11. Reflectance. loss change (db).5 3.4.3 25.2 2.1 15 -.1 1 -.2 5 -.3 -.4 -.5 4 8 12-5 16 time (h) Fig.12. Graph of thermal cycle test. temperature ( C) 2

Fig. 13. Overview of SC type. field installable optical connector for cables. The SC type has the same assemble flow, feature and structure as the LC type described in section 2 to 3. 6. Conclusion To expand the lineup of field-installable optical connectors, we have successfully developed the field-installable connector for Aramid yarn reinforced optical cables. This connector makes use of the established mechanical splice technique to terminate the optical cable with a unique way of securing Aramid yarn to the back of the connector plug, which has better installation ease and is less time consuming compared with conventional method. The connectors were evaluated and proven to exhibit exceptional optical performance and outstanding environmental and mechanical characteristics. We have accomplished the objectives set out for the development of the field-installable LC connector for Aramid yarn reinforced optical cables. Following this, we will continue our endeavors and employ similar technology to develop field-installable SC connector for cables and achieve further targets such as better optical, environmental and mechanical performance and increased ease of installation in optical networks. References 1) K. Terakawa, et al.: Aerial joint technology to realize large amount of optical construction, 26 IEICE General Conferences, 26 2) K.Takizawa, et al. : Field-Installable Connector for Optical Fiber, 47th IWCS,1998 3) K.Takizawa, et al. : MT-RJ Optical Connector, 48th IWCS, 1999 4) K.Takizawa, et al. : Development of New Mechanical Splice and Field-Installable Connector for FTTH, 52th IWCS,23 5) D.Saito, et al.: Development of Field-Installable Optical Connector for FTTH, 54th IWCS,25 6) Tan Khee Yen Serin, et al.: Field Installable LC Connector for Cables, OFCNFOEC 28 7) Tan Khee Yen Serin, et al.: Field Installable LC Connector and Mechanical Sílice, OFCNFOEC 27 Fujikura Technical Review, 29 21

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