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Abstract

An optical fiber–based full-field strain measurement technique was used to investigate delamination growth in laminated composites. An experimental setup to load the test samples under idealized modes of delamination was used to investigate the ability to capture the shape and location of the delamination front. It is envisioned that the demonstrated approach has significant field applications in controlled laboratory settings where delaminations have to be located accurately. Furthermore, the ability of this measurement system to provide full-field strain measurements at any given pre-implanted location through the thickness overcomes the surface strain measurements obtained by digital image correlation. In order to demonstrate the technique, distributed fiber optic sensing is used to monitor the propagation of delaminations under pure mode I and II loading. Optical fibers were embedded one ply from the crack plane of both double cantilever beam and end notch flexure specimens. To establish a repeatable fabrication methodology, manufacturing techniques for embedding the optical fibers during the laminate layup process were established. Specimens with and without embedded fibers were tested to verify the fibers did not affect measured fracture toughness values. Crack lengths measured with the optical fibers compared well with true crack lengths, and measured strain distributions compared well with results from finite element analysis.

Keywords

Optical strain sensing carbon composites fracture toughness delamination

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References

Diamanti

Soutis

Structural health monitoring techniques for aircraft composite structures. Prog Aerosp Sci 2010; 46(8): 342–352.

Kuang

KSC

Cantwell

. Use of conventional optical fibers and fiber Bragg gratings for damage detection in advanced composite structures: a review. Appl Mech Rev 2003; 56(5): 493–513.

Baker

Rajic

Davis

Towards a practical structural health monitoring technology for patched cracks in aircraft structure. Compos Part A Appl S 2009; 40(9): p. 1340–1352.

Boller

Staszewski

WJ.

Aircraft structural health and usage monitoring. In: Staszewski

Boller

Tomlinson

(eds) Health monitoring of aerospace structures. Hoboken, NJ: John Wiley & Sons, 2004, pp.29–73.

Chandler

Ferguson

Graver

et al . On-line structural health and fire monitoring of a composite personal aircraft using an FBG sensing system. In: Proceedings of SPIE: smart sensor phenomena, technology, networks, and systems, San Diego, CA, 9 March 2008. Bellingham, WA: SPIE.

Brockenheimer

Speckmann

. Validation, verification and implementation of SHM at Airbus. In: 9th international workshop on structural health monitoring (IWSHM 2013), Stanford, CA, September 2013, https://web.stanford.edu/group/sacl/workshop/IWSHM2013/documents/Keynote%20presentations/IWSHM%202013%20Keynote_Clemens%20Bockenheimer.pdf

Bernasconi

Carboni

Comolli

Monitoring of fatigue crack growth in composite adhesively bonded joints using Fiber Bragg Gratings. Procedia Eng 2011; 10: 207–212.

Shapira

Ben-Simon

Bergman

et al . Structural health monitoring of a UAV fleet using fiber optic distributed strain sensing. In: International workshop on structural health monitoring, Stanford University, Stanford, CA, 1–3 September 2015. Lancaster, PA: Destech Publications.

LUNA. OdisiA 2012, August 2012, http://lunainc.com

10.

NASA Armstrong FRC Fiber Optic Sensing System (FOSS), https://www.nasa.gov/offices/ipp/centers/dfrc/technology/Fiber-Optic-Sensing-Suite.html (accessed 18 June 2017).

11.

Minakuchi

Umehara

Takagaki

et al . Life cycle monitoring and advanced quality assurance of L-shaped composite corner part using embedded fiber-optic sensor. Compos Part A Appl S 2013; 48(1): 153–161.

12.

Kosters

Van Els

. Structural health monitoring and impact detection for primary aircraft structures. In: Proceedings of SPIE: fiber optic sensors and applications, Orlando, FL, 5 April 2010. Bellingham, WA: SPIE.

13.

Tsutsui

Kawamata

Sanda

et al . Detection of impact damage of stiffened composite panels using embedded small-diameter optical fibers. Smart Mater Struct 2004; 13(6): 1284–1290.

14.

Tsutsui

Kawamata

Kimoto

et al . Impact damage detection system using small-diameter optical-fiber sensors embedded in CFRP laminate structures. Adv Compos Mater 2004; 13(1): 43–55.

15.

Udd

. 25 years of structural monitoring using fiber optic sensors. In: Proceedings of SPIE: smart sensor phenomena, technology, networks, and systems, San Diego, CA, 6 March 2011. Bellingham, WA: SPIE.

16.

Loutas

Charlaftis

Airoldi

et al . Reliability of strain monitoring of composite structures via the use of optical fiber ribbon tapes for structural health monitoring purposes. Compos Struct 2015; 134: 762–771.

17.

Liao

Yang

et al . High-sensitivity temperature sensor based on a coated single-mode fiber loop. J Lightwave Technol 2015; 33: 4019–4026.

18.

Razali

Abu Bakar

Tamchek

et al . Fiber Bragg grating for pressure monitoring of full composite lightweight epoxy sleeve strengthening system for submarine pipeline. J Nat Gas Sci Eng 2015; 26: 135–141.

19.

Guo

Xiao

Mrad

et al . Fiber optic sensors for structural health monitoring of air platforms. Sensors 2011; 11(4): 3687–3705.

20.

Grave

JHL

Håheim

Echtermeyer

. Measuring changing strain fields in composites with distributed fiber-optic sensing using the optical backscatter reflectometer. Compos Part B: Eng 2015; 74: 138–146.

21.

Murayama

Wada

Kageyama

et al . Strain monitoring and damage detection of single-lap joint with embedded FBGs. In: Structural health monitoring 2011: condition-based maintenance and intelligent structures—proceedings of the 8th international workshop on structural health monitoring, Stanford University, Stanford, CA, 13–15 September 2011. Lancaster, PA: Destech Publications.

22.

Samiec

Distributed fibre-optic temperature and strain measurement with extremely high spatial resolution. Photonik International, 2012, http://www.photonik.de.

23.

D5528-13

Standard test method for mode I interlaminar fracture toughness of unidirectional fiber-reinforced polymer matrix composites. West Conshohocken, PA: ASTM International, 2013.

24.

ASTMD7905. Standard test method for determination of the mode II interlaminar fracture toughness of unidirectional fiber-reinforced polymer matrix composites. West Conshohocken, PA: ASTM International, 2014.

25.

Davidson

Teller

SS.

Recommendations for an ASTM standardized test for determining G_{II_c} of unidirectional laminated polymeric matrix composites. J ASTM Int 2010; 7: 1–11.

26.

Ranatunga

Clay

. Testing and analysis of the end-notched flexure specimen for composites under mode-II fracture. In: 26th annual technical conference of the American Society for Composites 2011 and the 2nd Joint US-Canada conference on composites, Montreal, QC, Canada, 26–28 September 2011. Red Hook, NY: Curran Associates, Inc.

27.

Shivakumar

Bhargava

Failure mechanics of a composite laminate embedded with a fiber optic sensor. J of Compos Mater 2005; 39(9): 777–798.

28.

ABAQUS. Dassault Systèmes.

Distributed optical sensing in composite laminates

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