环圈光纤的失效预测

Failure Prediction of Coiled Fibers

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摘要以光纤的机械可靠性为主线综述了光纤材料中固有裂纹的生长和传播所导致的光纤断裂机制.在该断裂力学的基础上推导了传统通信光纤在平直应用中的寿命预测模型.继而分析了处于弯曲构型中的传感环圈光纤表面的应力分布,然后在与传统理论相同的基本断裂机理下,类比于通信光纤可靠性模型的推导,据此应力分析给出了评估这种环圈光纤的机械可靠性的一般模型.进而从工程应用的角度简化了所推导出的一般模型,使之能够快速简单地给出环圈光纤失效概率的保守评估.在此简化模型的基础上,数值计算了目前常见的几种传感环圈中的光纤在服役期间的累积失效概率;其结果同时也显示了该环圈光纤的失效概率对光纤参量、环圈参量以及工艺参量的依赖关系.根据这一依赖关系,不仅可以快速评估在各种服役应力条件下具有不同寿命要求的光纤环圈的失效概率,同时也能对这些环圈的设计提供参考. The mechanism of crack occurrence and propagation in optical fibers were reviewed with emphasis on the reliability of optical fibers. The lifetime prediction model of communication optical fibers were given on the basis of the fracture mechanics. The stresses distribution of optical fibers in the configuration of fiber coils was analyzed. A general model was derived for evaluating the mechanical reliability of this kind of coiled sensing fibers. The model was then simplified to an alternative model for engineering applications. This simplified model would bring the conserved results out rapidly and simply. Several numerical calculations of the failure probability in service time of various fiber coils with different fiber radius and bending radius were carried out using the simplified model. The results displayed the dependence of the failure probability on the parameters of the fibers, coils, and the process. According to the relation, the failure probability and the lifetimes could be estimated for fiber coils installed. Meanwhile, the relations provided the guidelines to various design solutions of the fiber Coils with deferent geometric configurations and service conditions in the future.

作者梁小红刘军号

机构地区中国电子科技集团公司第四十六研究所

出处《光子学报》 EI CAS CSCD 北大核心 2013年第4期427-431,共5页 Acta Photonica Sinica

关键词光纤失效概率机械可靠性 Optical fibers Failure probability Mechanical reliability

分类号 TQ342.82 [化学工程—化纤工业]

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参考文献17

1NOE R. Essentials of modern optical fiber communication [M]. Heidelberg: Springer-Verlag Berlin Heidelberg, 2010.
2LECOY P. Fiber-optic communications[M]. New York: John Wiley & Sons, 2008.
3YIN S, RUFFIN P B, YU F T S. Fiber optic sensors[M]. 2nd ed. Boca Raton: CRC Press, 2008.
4RIGHINI G C, TAJANI A, CUTOLO A. An introduction to optoelectronic sensors [M]. Singapore: World Scientific Publishing Co. Pte. Ltd. , 2009.
5AZADEH M. Fiber optics engineering [M]. New York: Springer Science+Business Media, 2009.
6SIVALIGAM K M, SUBRAMANIAM S. Emerging optical network technologies [ M]. New York: Springer Science + Business Media, 2005.
7EVANS A G. A simple method for evaluating slow crack growth in brittle materials [J]. International Journal of Fracture, 1973, 9(3) : 267-275.
8EVANS A G, WIEDERHORN S M. Proof testing of ceramic materials-An analytical basis for failure prediction [ J ]. International Journal of Fracture, 1974, 10(3): 379-392.
9RITTER J E Jr. Probability of fatigue failure in glass fibers [J]. Fiber and Integrated Optics, 1978, 1(4): 387-399.
10KALISH D, TARIYAL B K. Static and dynamic fatigue of a polymer-coated fused silica optical fiber [J]. Journal of American Ceramic Society, 1981, 61(12): 518-523.

二级参考文献20

1SENIOR J M. Optical fiber communications princples and practice[M].London:Pearson Education Limited,2009.
2KAMINOW I P,LI T,WILLNER A E. Optical fiber telecommunications VB:systems and networks[M].Academic Press,Inc,2008.
3AGRAWAL G P. Fiber-optic communication systems[M].New York:John Wiley and Sons,2002.
4YIN S,RUFFIN P B,YU F T S. Fiber optic sensors[M].Boca Raton:crc Press,2008.
5RIGHINI G C,TAJANI A,CUTOLO A. An introduction to optoelectronic sensors[M].Singapore:World Scientific Publishing Co.Ptc.Ltd,2009,(1).doi:10.3899/jrheum.090674.
6GHATAK A,THYAGARAHAN K. Introduction to fiber optics[M].Cambridge:Cambridge University Press,1997.
7ROGERS A. Polarization in optical fibers[M].Nowood:Artech House,Inc,2008.
8HUI R,O' SULLIVIAN M. Fiber optic measurement techniques[M].San Diego:Elsevier Inc,2009.doi:10.3109/10903120903572335.
9BLACK R J,GAGNON L. Optical waveguide modes:polarization,coupling,and symmetry[M].New York:McGraw-Hill,2010.
10KUMAR A,GHATAK A. Polarization of light with applications in optical fibers[M].Bellingham:SPIE Press,2011.

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2张清明.光纤透明度的极限[J].国外激光,1992(1):28-28.
3非晶态聚酯拉伸丝及其制造方法[J].聚酯工业,2004,17(6):65-65.
4庄荣菊.机械可靠性在公路施工机械管理工作中的应用[J].中国科技博览,2010(18):314-314.
5王光宗,王济蓉.根据例行试验确定聚合物被覆和密封被覆光纤的机械可靠性[J].光纤光缆传输技术,1993(2):38-51.
6张显友,陈伟,周宏.光纤及其制造技术的最新进展[J].光纤与电缆及其应用技术,2001(3):4-8. 被引量：6
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8于杰,张小燕,吕禾青,何敏.聚氯乙烯断口分析及其断裂机制[J].贵州科学,1992,10(2):67-72. 被引量：1
9于杰,吕禾青,张小燕,何敏.聚氯乙烯断口分析及其断裂机制[J].高分子材料科学与工程,1992,8(4):111-115. 被引量：6
10生产增塑聚乙烯醇的方法及其用于制备淀粉基可生物降解的热塑性组合物[J].化工科技市场,2005,28(4):69-69.

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2013年第4期

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环圈光纤的失效预测

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