Perspective optical fiber sensors and their application (review)

Kachura S.M., Postnov V.I.
Kachura S.M., Postnov V.I. Perspective optical fiber sensors and their application (review) // Proceedings of VIAM. 2019. No. 5. DOI: 10.18577/2307-6046-2019-0-5-52-61. URL: https://test.viam.ru/en/journal/2019/5/6
Keywords
system of embedded monitoring, fiber optic monitoring system, structural health monitoring, fiber Bragg grating, polymer composite material, FRP, interrogator.
Abstract

A significant increase in the use of composite materials, including in aerospace engineering, as well as in other areas requiring increased reliability of structures, such as oil production, construction, etc. makes the task of monitoring the state of structures (SHM – structural health monitoring technology) very relevant. One of the most promising approaches is the use of fiber optic sensors as part of the monitoring system. Fiber optic sensors compared to classical sensors have a number of significant advantages.

This review article shows the variety of applications of fiber-optic embedded sensors in the field of aircraft structures made of polymer composite materials, and in the civil sphere. Considered promising fiber optic systems. The areas of application of such systems and the directions of their development are shown.

Reference list
  1. Kablov E.N. Tendentsii i oriyentiry innovatsionnogo razvitiya Rossii [Trends and benchmarks of innovative development of Russia]. M.: VIAM, 2015. 720 s.
  2. Kablov E.N. Shestoy tekhnologicheskiy uklad [The sixth technological structure] // Nauka i zhizn. 2010. №4. S. 2–7.
  3. Kablov E.N. Aviatsionnoye materialovedeniye: itogi i perspektivy [Aviation Materials: Results and Prospects] // Vestnik Rossiyskoy akademii nauk. 2002. T. 72. №1. S. 3–12.
  4. Kablov E.N. Innovacionnye razrabotki FGUP «VIAM» GNC RF po realizacii «Strategicheskih napravlenij razvitiya materialov i tehnologij ih pererabotki na period do 2030 goda» [Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030»] // Aviacionnye materialy i tehnologii. 2015. №1 (34). S. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
  5. Timoshkov P.N., Khrulkov A.V., Yazvenko L.N. Kompozitsionnye materialy v avtomobilnoy promyshlennosti (obzor) [Composite materials in automotive industry (review)] // Trudy VIAM: elektron. nauch.-tekhnich. zhurn. 2017. №6 (54). St. 07. Available at: http://www.viam-works.ru (accessed: March 19, 2019). DOI: 10.18577/2307-6046-2017-0-6-7-7.
  6. Doriomedov M.S., Daskovskij M.I., Skripachev S.Yu., Shein E.A. Polimernye kompozicionnye materialy v zheleznodorozhnom transporte Rossii (obzor) [Polymer composite materials in the Russian railways (review)] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2016. №7. St. 12. Available at: http://www.viam-works.ru (accessed: March 19, 2019). DOI: 10.18577/2307-6046-2016-0-7-12-12.
  7. Erasov V.S., Yakovlev N.O., Nuzhnyj G.A. Kvalifikatsionnye ispytaniya i issledovaniya prochnosti aviatsionnyh materialov [Qualification tests and researches of durability of aviation materials] // Aviacionnye materialy i tehnologii. 2012. №S. S. 440–448.
  8. Guo H., Xiao G., Mrad N., Yao J. Fiber Optic Sensors for Structural Health Monitoring of Air Platforms // Sensors. 2011. Vol. 11. P. 3687–3705.
  9. Mesquita E., Antunes P., Coelho F. Global overview on advances in structural health monitoring platforms // Journal of Civil Structural Health Monitoring. 2016. Vol. 6. P. 461–475.
  10. Kablov E.N., Sivakov D.V., Gulyaev I.N., Sorokin K.V., Fedotov M.Yu., Goncharov V.A. Metody issledovaniya konstrukcionnyh kompozicionnyh materialov s integrirovannoj elektromehanicheskoj sistemoj [Methods of research of constructional composite materials with the integrated electromechanical system] // Aviacionnye materialy i tehnologii. 2010. №4. S. 17–20.
  11. Zhu P., Xie X., Sun X., Sotoac M.A. Distributed modular temperature-strain sensor based on optical fiber embedded in laminated composites // Composites Part B: Engineering. 2019. Vol. 168. P. 267–273.
  12. Sante D.R. Fibre Optic Sensors for Structural Health Monitoring of Aircraft Composite Structures: Recent Advances and Applications // Sensors. 2015. Vol. 15. P. 18666–18713.
  13. Liokumovich L.B. Volokonno-opticheskiye interferometricheskiye izmereniya. Ch. 1. Volokonno-opticheskiye interferometry [Fiber optic interferometric measurements. Part 1. Fiber-optic interferometers]. SPb.: Izd-vo Politekhn. un-ta, 2007. 110 s.
  14. Yu H., Wang Y., Ma J., Zheng Z., Luo Z., Zheng Y. Fabry-Perot Interferometric High-Temperature Sensing Up to 1200°C Based on a Silica Glass Photonic Crystal Fiber // Sensors. 2018. Vol. 18. 273 p.
  15. Islam M.R., Ali M.M., Lai M.-H. et al. Chronology of Fabry-Perot Interferometer Fiber-Optic Sensors and Their Applications: A Review // Sensors. 2014. Vol. 14. P. 7451–7488.
  16. Lee B.H., Kim Y.H., Park K.S. et al. Interferometric Fiber Optic Sensors // Sensors. 2012. Vol. 12. P. 2467–2486.
  17. Yoshino T., Kurosawa K., Itoh K., Ose T. Fiber-optic Fabry-Perot interferometer and its sensor applications // IEEE Journal of Quantum Electronics. 1982. Vol. 4. P. 626–665.
  18. Vasilev S.A., Medvedkov I.O., Korolev I.G. i dr. Volokonnyye reshetki pokazatelya prelomleniya i ikh primeneniye [Fiber gratings of the refractive index and their application] // Kvantovaya elektronika. 2005. T. 35. №12. S. 1085–1103.
  19. Vyalyshev A.I., Dobrov V.M., Dolgov A.A. i dr. Volokonno-opticheskiye datchiki dlya kontrolya parametrov sostoyaniya obektov i okruzhayushchey sredy v zadachakh monitoringa // Prirodoobustroystvo. 2014. №3. S. 32–37.
  20. Kablov E.N., Startsev O.V., Medvedev I.M., Shelemba I.S. Volokonno-opticheskiye datchiki dlya monitoringa korrozionnykh protsessov v uzlakh aviatsionnoy tekhniki (obzor) [Fiber optic sensors for monitoring corrosion processes in units of aviation engineering (review)] // Aviacionnye materialy i tehnologii. 2017. №3 (48). S. 26–34. DOI: 10.18577/2071-9140-2017-0-3-26-34.
  21. Ganziy D., Bang O., Rose B. Technology for Polymer Optical Fiber Bragg Grating Fabrication and Interrogation // DTU Fotonik. 2017. 173 p.
  22. Cui J., Hu Y., Feng K. et al. FBG Interrogation Method with High Resolution and Response Speed Based on a Reflective-Matched FBG Scheme // Sensors. 2015. Vol. 15. P. 16516–16535.
  23. Ganziy D., Rose B., Bang O. Compact multichannel high-resolution micro-electro-mechanical systems-based interrogator for Fiber Bragg grating sensing // Applied Optics. 2017. Vol. 56. P. 3622–3627.
  24. Zhang W., Li Y., Jin B. et al. A Fiber Bragg Grating Interrogation System with Self-Adaption Threshold Peak Detection Algorithm // Sensors. 2018. Vol. 18. P. 1140.
  25. Njegovec M., Donlagic D. High-resolution spectrally-resolved fiber optic sensor interrogation system based on a standard DWDM laser module // Optics Express. 2010. Vol. 18. P. 24195–24205.
  26. Hartog A.H. An introduction to distributed optical fibre sensors. CRC Press, 2017. 442 r. 27. Bao X., Chen L. Recent Progress in Distributed Fiber Optic Sensors // Sensors. 2012. Vol. 12. P. 8601–8639.
  27. Motil A., Bergman A., Tur M. State of the art of Brillouin fiber-optic distributed sensing // Optics & Laser Technology. 2016. Vol. 78. P. 81–103.
  28. Wei H., Zhao X., Kong X. et al. The Performance Analysis of Distributed Brillouin Corrosion Sensors for Steel Reinforced Concrete Structures // Sensors. 2014. Vol. 14. Р. 431–442.
  29. Chandarana N., Martinez-Sanchez D., Soutis C., Gresil M. Early Damage Detection in Composites by Distributed Strain and Acoustic Event Monitoring // Procedia Engineering. 2017. Vol. 188. P. 88–95.
  30. Lan C., Zhou W., Xie Y. Detection of Ultrasonic Stress Waves in Structures Using 3D Shaped Optic Fiber Based on a Mach–Zehnder Interferometer // Sensors. 2018. Vol. 18. Р. 1–16.
  31. Sai Y., Zhao X., Hou D., Jiang M. Acoustic Emission Localization Based on FBG Sensing Network and SVR Algorithm // Photonic sensors. 2017. Vol. 7. No. 1. P. 48‒54.
  32. Fu T., Zhang Z., Liu Y., Leng J. Development of an artificial neural network for source localization using a fiber optic acoustic emission sensor array // Structural Health Monitoring. 2015. Vol. 14 (2). P. 168–177.
  33. Tian Z., Yu L., Sun X., Lin B. Damage localization with fiber Bragg grating Lamb wave sensing through adaptive phased array imaging // SAGE Publications Structural Health Monitoring. 2019. Vol. 17. Issue 1. P. 334–344.
  34. Jiang M., Sai Y., Geng X. et al. Development of an FBG Sensor Array for Multi-Impact Source Localization on CFRP Structures // Sensors. 2016. Vol. 16. P. 1770.
  35. Yu F., Okabe Y. Fiber-Optic Sensor-Based Remote Acoustic Emission Measurement in a 1000°C Environment // Sensors. 2017. Vol. 17. Р. 1–14.
  36. Dyshenko V.S., Raskutin A.E., Zuev M.A. Dorozhnyj detektor v sistemah bezostanovochnogo avtomaticheskogo vzveshivaniya [The road detector in systems of Weigh-In-Motion] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2016. №5. St. 12. Available at: http://www.viam-works.ru (accessed: February 27, 2019). DOI: 10.18577/2307-6046-2016-0-5-12-12.
  37. Makhsidov V.V., Yakovlev N.O., Ilichev A.V., Shiyenok A.M., Firsov L.L. Opredeleniye deformatsii materiala konstruktsii iz PKM s pomoshch'yu integrirovannykh optovolokonnykh sensorov [Determination of the deformation of the material of the construction of the PCM with the help of integrated fiber-optic sensors] // Mekhanika kompozitsionnykh materialov i konstruktsiy. 2016. T. 22. №3. S. 402–413.
  38. Makhsidov V.V., Reznikov V.A. Proyekty, napravlennyye na razrabotku tekhnologii vstroyennogo kontrolya konstruktsiy iz PKM [Projects, aimed to development of structural health monitoring system for CFRP structures] // Novosti materialovedeniya. Nauka i tekhnika: elektron. nauch.-tekhnich. zhurn. 2017. №5–6 (28). St. 04. Available at: http://materialsnews.ru/ru/ (accessed: January 28, 2019).
  39. Isayev V.G., Seregin N.G., Grechanaya N.N. Izmereniye deformatsiy konstruktivnykh elementov tekhnicheskikh sistem letatelnykh apparatov volokonno-opticheskimi ustroystvami [Measurement of deformations of structural elements of technical systems of aircraft by fiber-optic devices] // Informatsionno-tekhnologicheskiy vestnik. 2018. №2 (16). S. 14–24.
  40. Vaynshteyn E.F., Solodysheva E.S., Krivolutskaya I.I. Eksperimentalnoye issledovaniye deformatsionnykh kharakteristik polimernykh i kompozitsionnykh materialov pri zadannykh postoyannykh vneshnikh usloviyakh [Experimental study of the deformation characteristics of polymeric and composite materials under given constant external conditions] // Konstruktsii iz kompozitsionnykh materialov. 2014. №1 (133). S. 52–56.
  41. Sarbayev B.S., Smerdov A.A., Tairova L.P., Selezenev V.A. Issledovaniye deformirovannogo sostoyaniya konstruktsiy iz kompozitsionnykh materialov s pomoshch'yu volokonno-opticheskikh datchikov [Investigation of the deformed state of structures made of composite materials using fiber-optic sensors] // Vestnik Moskovskogo gosudarstvennogo tekhnicheskogo universiteta im. N.E. Baumana. Ser.: Mashinostroyeniye. 2011. №S1. S. 39–51.
  42. Ramakrishnan M., Rajan G., Semenova Y., Farrell G. Overview of Fiber Optic Sensor Technologies for Strain/Temperature Sensing Applications in Composite Materials // Sensors. 2016. Vol. 16. R. 1–27.
  43. Sierra-Perez J., Torres-Arredondo M.A., Guemes A. Damage and nonlinearities detection in wind turbine blades based on strain field pattern recognition. FBGs, OBR and strain gauges comparison // Composite Structures. 2016. Vol. 135 P. 156–66.
  44. Makhsidov V.V., Shiyenok A.M., Ioshin D.V., Reznikov V.A. Izmereniye deformatsii materiala s pomoshchyu volokonnykh breggovskikh reshetok (obobshchayushchaya statya) [Measurement of material deformation using fiber Bragg gratings (generalizing article)] // Zavodskaya laboratoriya. Diagnostika materialov. 2014. T. 82. №3. S. 54–60.
  45. Raskutin A.E., Makhsidov V.V., Smirnov O.I., Kasharina L.A. Monitoring nagruzhennosti kompozitnoy konstruktsii arochnogo mosta na osnove volokonno-opticheskikh datchikov [Monitoring of the deformability of the composite structure of the arch bridge based on fiber-optic sensors] // Trudy VIAM: elektron. nauch.-tekhnich. zhurn. 2018. №3 (63). St. 06. Available at: http://www.viam-works.ru (accessed: January 28, 2019). DOI: 10.18577/2307-6046-2018-0-3-49-59.
  46. Leduc D., Lecieux Y., Morvan P.-A., Lupi C. Architecture of optical fiber sensor for the simultaneous measurement of axial and radial strains // Smart Materials and Structures. 2013. Vol. 22. P. 1–9.
  47. Zhelezina G.F., Sivakov D.V., Gulyayev I.N. Vstroyennyy kontrol: ot datchikov do informkompozitov [Built-in control: from sensors to information composites] // Aviatsionnaya promyshlennost. 2008. №3. S. 46–50.
  48. Fedotov M.Yu., Sorokin K.V., Goncharov V.A., Shiyenok A.M., Zelenskiy P.V. Vozmozhnosti sensornykh sistem i intellektualnykh PKM na ikh osnove [Possibilities of sensor systems and intelligent PCM based on them] // Vse materialy. Entsiklopedicheskiy spravochnik. 2013. №2. S. 18–23.
  49. Sun J., Guan Q., Liu Y., Leng J. Morphing aircraft based on smart materials and structures: A state-of-the-art review // Journal of Intelligent Material Systems and Structures. 2016. Vol. 27 (17). P. 2289–2312.
  50. Sonnenfeld C., Sulejmani S., Geernaert T., Eve S. Microstructured Optical Fiber Sensors Embedded in a Laminate Composite for Smart Material Applications // Sensors. 2011. Vol. 11. P. 2566–2579.
  51. Yan W., Page A.G., Nguyen D.T. et al. Advanced Multi-Material Electronic and Optoelectronic Fibers and Textiles // Advanced materials. 2019. Vol. 31. Issue 1. P. 1–28.
  52. Khudiyev T., Clayton J., Levy E. et al. Electrostrictive microelectromechanical fibres and textiles // Nature Communications. 2017. Vol. 8. Article number: 1435.
  53. Haque M., Lee K., Ho S. et al. Chemical-assisted femtosecond laser writing of lab-in-fibers // Lab on Chip. 2014. Vol. 14. P. 3817–3829.
  54. Danto S., Sorin F., Orf N. et al. Fiber Field-Effect Device Via In Situ Channel Crystallization // Advanced materials. 2010. Vol. 22. P. 4162–4166.