New Mass Fusion Splicer FSM-50R Series Hiroshi Sugawara, Kenji Takahashi, Kohji Ohzawa, Taku Ohtani, Manabu Tabata, Tomohiro Konuma and Toshihiro Tsuchida Fixed V-groove fusion splicers are commonly used in the installation of fiber optic cables, including FTTx applications, in Japan and rest of the world. Splicer users, especially those deploying new FTTx applications, are increasingly requiring splicers to be light and have a compact form factor, in addition to being fast and easy to use. Fujikura has introduced several new fixed V-groove splicers to meet these requirements. The FSM-50R is used to splice up to 12-fiber ribbons, the FSM-17R is used for splicing up to 4-fiber ribbons, and the FSM-17S is used for single fiber splices. Each of these splicers includes multiple advanced features to meet the requirements of customers in Japan and rest of the world. Arc power is controlled according to the brightness of the fiber at the time of arc discharge in auto mode. 1. Introduction In recent years, the core of the optical network communications infrastructure has been installed in Asia, especially in China. In Japan and the United States, FTTP applications that connect homes and offices to the network are increasing. The diverse conditions for installing optical fiber networks require optical fiber fusion splicers not only to be small and light but also to have short splicing and protection sleeve shrinking times. In order to meet these requirements, we have developed the fixed V-groove fusion splicer series that consists of the FSM-50R for up to 12-fiber ribbons, the FSM-17R for up to 4-fiber ribbons and the FSM-17S for single fiber splicing. This lineup is shown in Table 1. Significant characteristics of the FSM-50R series are: (1) Shortest splicing time: 20 s for 12-fiber ribbons. This is the fastest splicing time of all 12-fiber ribbon splicers in the world. (2) Lightest weight: 2.65 kg (including the standard battery). This is the lightest weight of all 12-fiber ribbon splicers in the world. (3) Easy operation: equipped with automatic fiber arrangement guide. (4) Reduced number of steps to make a splice (5) Real-time arc power control 2. Product Overview The FSM-50R is shown in Fig.1. A comparison of specifications between the old models and the new models is shown in Table 2. 3. Details 3.1 Reducing Splicing and Heating Times 3.1.1 Reducing Splicing Time In the FSM-50R splicer, motors controlling the fiber movements (advancing and receding) have been innovated so that the time required to set the fiber ends face to face is much shorter than that with older models. Software and hardware were designed Table 1. New Splicer Lineup Model name Applicable fiber count FSM-50R 1 to 12 FSM-17R 1 to 4 FSM-17S 1 (Sheath clamp type) FSM-17S-FH 1 (Fiber holder type) Fujikura Technical Review, 2005 Fig. 1. Appearance of New Fusion Splicer. 17 Table 2. Comparison of Specifications Item New model FSM-50R Old model FSM-30R 150×150×150 mm 150×150×150 mm 2.65 kg 3.1 kg 1. Appearance Dimensions Weight (with AC adapter) 2. Splicing performance Average splice loss 0.05 dB (SMF) 0.05dB (SMF) Splice time 20 seconds 30 seconds Protection sleeve shrinkage time 45 seconds 100 seconds 140 splices (When using Battery-L*) 30 splices Number of splices & shrinks with charged battery 3.3 Enhancing Easy and Simple Operation 3.3.1 Structure Around V-grooves 3. Performances and functions related to operations Steps to make a splice 11 22 Time to make a splice 93 sec/splice 178 sec/splice Protection sleeve position adjustment function − Possible Impossible 5.6 inches 5.0 inches Assistance of operation Dual monitor position (front/rear) Monitor size instrument but also a durable one. It is also important that the splicers are portable because the splicers are frequently used at the top of a utility pole and inside of a manhole, which means the splicers need to be small and light. In order to meet these requirements, magnesium die-castings have been used with the main parts and the components of the new model are optimized to be durable and light. As a result, FSM-50R is the lightest 12-fiber ribbon splicer in the world (2.65 kg, including an AC adapter). 4. Functions for certain splices Arc power calibration Automatic Manual Fiber arrangement Automatic Manual Fiber arrangement in tube heater Automatic Manual When splicing fibers in aerial FTTP installations, it was difficult for the operators to set fibers in the narrow-pitched V-grooves of mass fusion splicers when the operators were not in a comfortable working position. In addition, when splicing fibers in underground trunk cables, operators needed additional light if it was too dark to see the V-grooves and set the fibers in them. The FSM-50R significantly improves the operability of the splicer under these conditions by making the fiber-setting process very easy using the improvements described below: * Option to increase the calculation speed for splice loss estimation. The result is the time required to splice has been reduced to 20 s on average. 3.1.2 Reducing Protection Sleeve Shrinking Time In order to avoid bubbles remaining inside of the protection sleeve during shrinking, it is necessary for the center of the sleeve to shrink before the sleeve ends. The tube heater in the older splicer models has only one heat source at the center of the tube heater such that there is a heat gradient that enables the sleeve center to shrink before the ends. The tube heater built in the new model has a strong heat source at the center of the heater and rather weak heat sources at both the ends of the heater. The structure realizes an ideal heat gradient and provides much more heat to the sleeves than the old model. The result is that it takes only 40 s to shrink 40 mm sleeves applicable for up to 12-fiber ribbons, and only 45 s to shrink sleeves applicable for up to 4-fiber ribbons or 8-fiber ribbons. 3.2 Reducing Weight Fixed V-groove fusion splicers are commonly used in the installation of the fiber optic cables. This situation requires the splicers to be not only a precision 18 1. The widths of fiber catcher grooves on fiber holders are optimized for each applicable fiber ribbon width. 2. The play between fiber holders and the z-stage is optimized. 3. An automatic fiber arrangement guide has been developed. The guide arranges fibers on the Vgroove automatically so that operators do not have to arrange fibers manually when fibers are set on the splicers. The outline of fiber arrangement guide is shown in Fig. 2. 3.3.2 Reducing Operations Needed to Make a Splice In the FSM-50R, the required operation count has been reduced to 11 and the time spent at the splicer to make a splice is 93 s. This is 85 s shorter than that of the older model, as shown in Table 3. Total operation time, including fiber preparation, has been reduced to approximately 3 min. The single fiber splicer FSM-50S has a special device that assists operators to bring both the splice point and protection sleeve to the center of the tube heater. The same function is also installed in the FSM-50R. In addition, the tube heater unit has a function to tension fibers in order to arrange them auto- Table 3. Comparison of Splice Operation Fiber clamp FSM-50R (New model) FSM-30R (Old model) 11 operations to make a splice 93 seconds 22 operations to make a splice 178 seconds 1. Place the left fiber holder. 2. Place the right fiber holder. 5 sec 3. Close the wind protector cover. 1. Set the left fiber holder, close the holder clamp. 2. Set the right fiber holder, 15 close the holder clamp. sec 3. Set the left fiber clamp. 4. Set the right fiber clamp. 5. Close the wind protector cover. 6. Press the SET key. V-groove Fiber guide Projection Step 1. In case an operator sets fibers out of V-grooves. Fiber guide arranges the fibers in order. Fiber clamp is lifted up. 20 sec Fiber guide moves upward. Step 2. Fiber guide moves upward just after the wind protector cover closed. The clamp holds fibers into the V-grooves as the fiber guide moves downward. The fibers have been arranged in the V-grooves. Fiber guide moves down so that the fibers are detached from the guide. Splicing 4. Open the wind protector cover. 5. Open the left fiber holder cover. 6. Open the right fiber holder cover. 7. Remove the fiber from the holders. 8. Adjust the position of the protection sleeve. 9. Set the fiber in the tube 20 heater. sec 10. Press HEAT key. Fber guide moves down. Step 3. Fiber guide moves downward. Fig. 2. New Fiber Guide System. matically just after starting the heating process. Operational capabilities of the tube heater have significantly improved with these functions. 3.3.3 Flexible Direction The optimum placement of the splicer relative to the operator changes depending on the surplus length of fibers to be spliced, relative position between the splicer and closures, and so forth. The FSM-50R has keyboards not only in the front side but also in the backside. The image on the monitor can be displayed upside down by the software setting when the monitor is tilted up. These functions allow the operators to use the splicers from various directions as needed. 3.4 Preventing Faulty Splice 3.4.1 Real-time Automatic Arc Calibration In order to make stable low loss ribbon splices, it is important that the heat to the fibers is distributed adequately. Fujikura Technical Review, 2005 45 sec Heating the sleeve 11.Remove the fiber from the splicer. 3 sec Splicing 7. Open the wind protector cover. 8. Remove the left fiber clamp. 9. Remove the right fiber clamp. 10.Open the cover-1 of the left fiber holder. 11.Open the cover-1 of the right fiber holder. 12.Open the cover-2 of the left fiber holder. 13.Open the cover-2 of the right fiber holder. 14.Remove the fiber from the holders. 15.Adjust the position of the protection sleeve. 16.Set the fiber in the tube heater. 17.Adjust the position of the splice point. 18.Close the cover of the tube heater. 19.Press HEAT key. 30 sec 30 sec Heating the sleeve 100 sec 20.Remove the fiber from the splicer. 21.Open the left holder clamp, remove the fiber holder. 22.Open the right holder clamp, remove the fiber holder. 3 sec However, the heat applied to the fibers is not stable even if the discharge current and discharge voltage are kept constant because the environmental conditions are always different, such as air pressure, temperature, humidity and wear of electrodes. Splice loss increases when the heat applied to the fiber goes out of the acceptable range due to this instability. Older splicers had sensors that measured the environmental conditions and the splicers adjusted arc discharge power according to the measured results. However, the old splicers were still required to calibrate the arc discharge power with a special function before splicing because the condition of electrodes 19 was not referenced yet. The special arc calibration function measured meltback amount of fibers after arc discharge, so the splicers estimated the distributed heat and calibrate X Y 1 2 Fig. 3. Thermal Luminescence of Optical Fiber. Intensity of thermal Iuminescence (A.U.) 1 35 69 103 137 171 205 239 273 307 341 375 409 443 477 No.1 1 2 Fig. 4. Analyzed Fiber Luminescence. the arc power setting. The function consumed time because operators needed to prepare a pair of cleaned and cleaved fibers to perform this function. The splicers could not ensure low splicing loss when the function was not performed. In order to resolve these problems, automatic realtime arc calibrating function similar to the function of the FSM-50S has been installed in the FSM-50R series. The splicers observe the thermal luminescence of the optical fibers and adjust arc discharge power automatically according to the amount of luminescence. Figure 3 shows an example of thermal luminescence during a splice. The distributed heat can be calculated from the sum of the brightness data that are picked up by vertical scan from the image. For example, Figure 4 illustrates the brightness data under vertical scan lines 1 and 2. The melt-back amount provides a consistent relation to the distributed heat for the fibers. Figure 5 shows the example of the relation between melt-back amount and thermal luminescence. Figure 6 shows the relation between arc discharge current and thermal luminescence. Though the degree of thermal luminescence depends on the fiber number, fiber position and environmental conditions, the correlation between the luminescence and the arc discharge current is always stable when the conditions are the same. Therefore, the required discharge current compensation can be calculated from the difference between the measured luminescence and the luminescence under the referenced adequate heat condition. Otherwise, adequate heat quantity can be distributed to the fibers by compensating discharge time instead of compensating discharge current. Required discharge time compensation is also calculated from the difference of luminescence. This discharge time 700 No.1 No.2 No.3 No.4 No.5 No.6 No.7 No.8 No.9 No.10 No.11 No.12 35 Intensity of luminescence (a.u.) Melt-back amount (µm) 600 500 400 300 200 100 30 25 20 15 10 5 0 0 0 100 200 300 Intensity of luminescence (a.u.) Fig. 5. Relation between Melt-back Amount and Thermal Luminescence. 20 18 20 22 24 26 28 30 32 19 21 23 25 27 29 31 33 Arc discharge current (mA) Fig. 6. Relation between Arc Discharge Current and Thermal Luminescence. compensation method can be applied when discharge current should be constant or its range is limited. As mentioned above, real-time arc calibration is performed using feedback loop, using the difference between the measured luminescence and the adequate luminescence to the arc discharge time. Therefore, the function provides stable low splicing loss under any environmental condition without measuring the melt-back amount. Fujikura Technical Review, 2005 4. Conclusion A new mass fusion splicer series has achieved the fastest splicing time and lightest weight, and provides easy and simple operation and consistent low splicing loss without the performance of any special function by the operators. These advantages decrease the operation time and cost and increase the reliability of splices under any environmental conditions. 21