光纤折射率的依赖因素

叙述光纤折射率与组成、温度、波长、模场直径和拉丝张力（拉丝温度）以及衰减等因素的相互依赖关系。指出拉制光纤时要严格控制拉丝张力,以防止因拉丝张力不当而引起的光纤折射率变化和衰减增加。     

偏振保持光纤的模式双折射

偏振保持光纤是单模光纤的一种特殊类型,其模式双折射与温度、芯和皮折射率差及椭圆度、热膨胀系数、光纤直径、弹性模量、泊松比、频率、波长、拉丝张力等诸多因素有关,对与偏振保持光纤模式双折射相关的上述因素进行分析,指出光纤模式双折射越高,光纤的偏振态保持就越好,为更好地设计新型保偏光纤或合理选择保偏光纤类型奠定了基础.     

负色散斜率的色散补偿光纤的研制

对三包层的大负色散、负色散斜率的色散补偿光纤进行了理论研究，分析了各个参量对色散曲线的调节作用，发现色散补偿光纤只有在一定范围的拉丝芯径内，以牺牲负色散数值才能大负色散斜率，采用在光纤拉丝时旋转预制棒的工艺减小了光纤的偏振模色散进一步改进国内已有的的改进的化学汽相沉积（ＭＣＶＤ）光纤生产工艺，研制出了较高水平的色散补偿光纤。     

通信系统中色散补偿光纤的研究

对五包层色散补偿光纤进行了研究,分析了各个参量对色散补偿光纤性能的影响,发现色散补偿光纤只有在一定范围的拉丝芯径内,以牺牲负色散数值为代价才能获得较大的负色散斜率。在1550nm处获得了不大于150ps/(nm·km)的负的总色散和负色散斜率的色散补偿光纤。采用在光纤拉丝时旋转预制棒的工艺减小了光纤的偏振模色散,并采用化学汽相沉积(MCVD)光纤生产工艺,研制出了性能较好的色散补偿光纤。     

三段加热系统对大尺寸MPOF预制棒一步拉伸工艺

采用自行设计的微结构聚合物光纤专用拉丝系统对大尺寸微结构聚合物光纤预制棒的一步拉伸工艺进行了研究.该微结构聚合物光纤加热系统采用三段式梯度加热,可保持炉内温度的控制准确度在±2℃以内.在保持送料速度与牵引速度恒定、协调的条件下,通过对温度场温度梯度控制优化,确定了最佳拉丝温度组合,并得到了直径规格310 μm、标准偏差为±20 μm的较高质量的微结构聚合物光纤.     

多包层光纤中的等效阶跃光纤方法

本文将等效阶跃光纤方法（ＥＳＦＭ）推广到多包层光纤,当已知多包层坯棒折射率分布,则利用这种方法可严格计算出核坯棒的等效阶跃光纤的等效折射率差,从而可方便地估算出该坯棒拉制出光纤的各种传输参数。文中以计算双包层椭圆光纤的截止波长为例作为部分验证。理论计算和实际测量的结果表明,除个别情况外,精度达到５％。因而,在工程解决了为确定多包层光纤的截止波长（或拉丝半径）,而必须进行重复凑试拉丝和测量的困难,大     

氟锆酸盐玻璃光纤的研制

本文介绍聚全氟乙丙烯包皮的氟锆酸盐(ZrF_4-BaF_2-LaF_3-AlF_3-NaF)玻璃光纤的制备方法.研究了各种工艺因素对氟锆酸盐玻璃和光纤散射损耗的影响.结果表明,选择适当的熔化温度和均化时间,玻璃熔化和光纤拉制时环境中低的水含量是制得的损耗氟锆酸盐玻璃光纤的关键;配合料中引入适量NH_4HF_2,选用温度结构合理的拉丝炉及拉丝工艺也有助于降低光纤的损耗.在此工作基础上,获得了波长2.32μm处损耗为0.24dB/m的氟锆酸盐玻璃光纤.     

拉制传像束用光纤双坩埚的设计

本文详细讨论了拉制用于制做传像束光纤的技术要求、实现的条件和双坩蜗的设计方法,给出了设计计算公式和理论误差计算公式,并对设计中的一些问题提供了合理而实际的解决方法。同时提出了低温拉丝以提高光纤透过率的新工艺。     

复合张力模糊控制系统设计

张力控制是光纤弹性材料缠绕工艺中的一项关键技术, 它直接影响到缠绕制品的质量。提出一种基于线速度差张力产生原理、微特直流力矩电机为施力机构的复合张力控制系统总体方案,实现对张力的精密控制。在对复合张力控制系统进行了建模分析基础上,模拟真实光纤环缠绕环境,采用模糊控制策略,仿真验证了复合张力控制系统的控制效果,对卷径的变化具有较强适应能力,具有响应快、超调量小、精度高的优点。     

多模梯度石英光纤拉丝、涂复技术及对光、力学性能的影响

本文描述了多模梯度石英光纤的拉丝、涂杂技术及其对光纤性能影响,对于GeO_2-P_2O_5-SiO_2三元系采用该技术可望获得强度～100kpsi,0.85μm损耗～2.5db/km,1.30μm损耗～0.7db/km,丝径125±3μm的涂复均匀、同心度良好的一次涂复光纤。文后列有一批反映工艺重复性的数据。     

Numerical Simulation of the Melt Spinning Process of Noncircular Fibers Incorporating Surface Tension

Incorporating surface tension, a mathematical modeling system was established to simulate the melt spinning process of a noncircular fiber. A Newtonian fluid was assumed and an isothermal spinning process was considered. Finite element method was adopted to solve the system. The predicted shape of as‐spun fiber was compared with experiments. It was found that surface tension was a key factor in the spinning process of noncircular fibers, which would greatly change the fiber cross‐sectional shape. Simulation would fail to predict the noncircular fiber shape accurately if surface tension was ignored. The fiber shape change caused by the velocity rearrangement only occurs near the spinneret, but surface tension would keep changing the curvature of the fiber surface along the spinline. Die swell of fiber extrudate during the spinning process was also investigated and it was found that die swelling of fiber extrudate near the spinneret was greatly suppressed by the stretch imposed by a take‐up device, when compared with the free extrusion process.     

带宽可调的斜边光纤光栅滤波器的设计与制作

基于遗传算法设计了斜边三角形光纤光栅(EFBG)的折射率调制函数;提出了光纤外径沿轴向变化、在拉应力下可获得可调谐的斜边三角形光纤光栅;计算分析了该器件多个物理参量对反射光谱的影响。在实验中,采用紫外激光扫描辐照方法,制备了短波边斜边带宽为0．7nm、反射率为96％的斜边三角形光纤光栅;采用程序控制氢氟酸腐蚀方法获得外径从原始62．5μm减小到45μm、在85mm长度内按设计要求变化的光纤光栅。对该光纤光栅施加从。到1．715N变化的拉力时,其反射光谱短波边的斜边带宽从0．7nm增加到2．3nm,实现了一种带宽大范围可调的斜边光纤光栅。     

Interfacial Tension and Fiber Lifetime of Ionomer‐Compatibilized Blends Investigated by Embedded Fiber Retraction

Embedded fiber retraction was used to investigate the interfacial tension and fiber lifetime of an immiscible polyester/polyamide system, with and without ionic functionality incorporated onto the polyester as compatibilizing groups. The ionic groups reduce the interfacial tension of the system from 7.55 dyne/cm to 1.49 dyne/cm when incorporated at 5.5 mole% into the polyester. In addition, fiber lifetime increased by a factor of 4–5 with the incorporation of ionic functionality. These results correlate extremely well with previously published observations of the ionomer‐compatibilized blends and confirm the influence of interfacial tension on blend morphology. The initial aspect ratio of the fiber should be between three and 12 for consistent and reproducible results.     

评估环圈光纤机械可靠性的模型

为评估应用于光纤陀螺和光纤电流传感器等传感领域的光纤环圈的机械可靠性,排除光纤涂覆和环圈灌胶等因素,必须评估所用光纤在弯曲状态下的机械可靠性.在已被广泛接受的均匀拉伸应力状态下通信光纤的机械可靠性模型基础上,根据这种环圈光纤在弯曲状态下的一般应力分布,对于绕环张力和弯曲应力同时存在的情形,建立了评估这种环圈光纤的机械可靠性的一种模型.该模型通过采用弯曲状态下光纤表面的最大弯曲应力值,和由于一般情况下弯曲中轴内侧的压缩应力远小于外侧拉伸应力的这一事实而忽略内侧的压缩应力,从而简化了弯曲应力的不均匀分布;同时通过该模型中所含的多个参量的选择给出了最为保守的结果.利用该模型进行的数值计算预测了采用不同直径的光纤分别绕制的不同环圈直径的环圈光纤在不同服役条件下的机械可靠性.结果表明,除了光纤半径和疲劳因子等这些光纤自身的固有因素外,绕环张力、环圈半径和筛选张力等工艺参量对环圈光纤的机械可靠性也是有重要影响.     

评估环圈光纤机械可靠性的模型

为评估应用于光纤陀螺和光纤电流传感器等传感领域的光纤环圈的机械可靠性,排除光纤涂覆和环圈灌胶等因素,必须评估所用光纤在弯曲状态下的机械可靠性.在已被广泛接受的均匀拉伸应力状态下通信光纤的机械可靠性模型基础上,根据这种环圈光纤在弯曲状态下的一般应力分布,对于绕环张力和弯曲应力同时存在的情形,建立了评估这种环圈光纤的机械可靠性的一种模型.该模型通过采用弯曲状态下光纤表面的最大弯曲应力值,和由于一般情况下弯曲中轴内侧的压缩应力远小于外侧拉伸应力的这一事实而忽略内侧的压缩应力,从而简化了弯曲应力的不均匀分布;同时通过该模型中所含的多个参量的选择给出了最为保守的结果.利用该模型进行的数值计算预测了采用不同直径的光纤分别绕制的不同环圈直径的环圈光纤在不同服役条件下的机械可靠性.结果表明,除了光纤半径和疲劳因子等这些光纤自身的固有因素外,绕环张力、环圈半径和筛选张力等工艺参量对环圈光纤的机械可靠性也是有重要影响.     

高功率光纤端帽实现6kW激光输出

高功率光纤端帽是kW级光纤激光器必不可少的器件,而实现光纤端帽的低损耗高强度熔接是其关键技术。由于光纤和大尺寸光纤端帽在直径上的巨大差异,二者的熔接不能通过传统熔接机实现。设计并搭建了光纤端帽熔接系统,掌握了多种尺寸的光纤端帽的熔接工艺,成功用于光纤激光器及光纤合束器的高功率输出。实验上利用单模光端帽实现了3.01kW的激光输出,在未进行主动制冷的情况下温升为7℃/kW。利用多模光纤端帽实现了6.08kW的激光输出,在未进行主动制冷的情况下温升为6℃/kW。     

温度补偿的悬臂梁光纤光栅力传感研究

本文提出了一种新颖的基于悬臂梁结构的光纤光栅力传感方法,将光纤光栅粘贴在悬臂梁和固定端基板的结合处,利用梁与基板对力和温度的不同响应,成功地实现了对力和环境温度的同时传感测量,消除了由于温度变化所引起的交叉敏感对传感测量准确性的影响.基于光谱分析仪0.1nm的光谱分辨率,实验可得到的力的测量分辨率为0.03N,测量范围可达1.5N,温度分辨率为3.4℃(力不变时可达0.86℃).实验结果与理论分析基本一致.     

Optical fiber cables using V-grooved cylindrical units: High performance cables

Some practical and theoretical aspects of a V-grooved cylindrical cable (high performance optical fiber cable) are now being developed in several countries. Design of cables is important, because bendings may cause distortions. In order to limit micro-bending losses in an optical fiber cable, it is possible to modify parameters relating to the fiber or the cable. Some of the possibilities are: to decrease the core diameter in order to decrease the attenuation coefficient; to increase the diameter of the cladding so as to increase the tension above which micro-bendings occur; to increase the continuous bending radius due to cabling; to decrease the effects of roughness (μ); to integrate the effects of roughness as much as possible by decreasing the Young modulus of the coating and of the cable material and by increasing the cladding thickness; and to suppress the tension T of the fiber in the cable. The cabling element is made of a V-grooved cylindrical core, in which the fiber with an outside diameter d_e (outside diameter or primary coating) are laid without tension, with a slight excess length. The slots with a depth h are helical or alternated helical, providing the possibility of additional excess length, and the fiber can be “cabled” directly without stresses. A central strength member with a diameter Dp reinforces the cylindrical rod, ensuring the mechanical and thermal qualities.     

Optical fiber cables using V-grooved cylindrical units: High performance cables

Some practical and theoretical aspects of a V-grooved cylindrical cable (high performance optical fiber cable) are now being developed in several countries. Design of cables is important, because bendings may cause distortions. In order to limit micro-bending losses in an optical fiber cable, it is possible to modify parameters relating to the fiber or the cable. Some of the possibilities are: to decrease the core diameter in order to decrease the attenuation coefficient; to increase the diameter of the cladding so as to increase the tension above which micro-bendings occur; to increase the continuous bending radius due to cabling; to decrease the effects of roughness (μ); to integrate the effects of roughness as much as possible by decreasing the Young modulus of the coating and of the cable material and by increasing the cladding thickness; and to suppress the tension T of the fiber in the cable. The cabling element is made of a V-grooved cylindrical core, in which the fiber with an outside diameter d_e (outside diameter or primary coating) are laid without tension, with a slight excess length. The slots with a depth h are helical or alternated helical, providing the possibility of additional excess length, and the fiber can be “cabled” directly without stresses. A central strength member with a diameter Dp reinforces the cylindrical rod, ensuring the mechanical and thermal qualities.