Sage Journals: Discover world-class research

Abstract

In this article, a recently proposed long-period fiber grating sensor coated with a thin layer of polyurethane and nano iron/silica particles is further developed and applied to monitor the corrosion process of deformed steel bars. Once calibrated, one coated long-period fiber grating sensor and one uncoated long-period fiber grating sensor for environmental compensation were attached to each of three steel bar samples that were tested in 3.5 wt% NaCl solution for 512 h. The resonant wavelength in long-period fiber grating spectra increased exponentially with immersion time due to corrosion of iron particles and thus reduction in coating thickness. The mass loss rate of steel bar #1 at the completion of corrosion tests (512 h of corrosion time) was correlated with that of sparse iron particles on long-period fiber grating sensor #1 after 130.5 h of immersion. The corrosion rates of long-period fiber grating sensors #2 and #3 were evaluated at 130.5 h and then used as a prediction of the corrosion rates of steel bars #2 and #3. The predicted corrosion rates by the long-period fiber grating sensors #2 and #3 were finally compared with those by potentiodynamic tests. The maximum mass loss prediction error by the long-period fiber grating sensors #2 and #3 is 26%. The coefficients of variation of three corrosion rate measurements are 0.049 by the long-period fiber grating sensors and 0.115 by the potentiodynamic tests, indicating more consistent and reliable measurements with the proposed technology.

Keywords

Steel corrosion long-period fiber gratings nano iron particles polyurethane

Get full access to this article

View all access options for this article.

References

Koch

. Corrosion cost and preventive strategies in the United States. Publication no. FHWA-RD-01-156, 2002. Washington, DC: FHWA, U.S. Department of Transportation.

Huang

Gao

Chen

. Long period fiber grating sensors coated with nano iron/silica particles for corrosion monitoring. Smar Mat St2013; 22: 0750182.

ASTM G96-90. Standard guide for online monitoring of corrosion in plant equipment (electrical and electrochemical methods). West Conshohocken, PA: ASTM International, 2008.

Mansfeld

. Electrochemical methods of corrosion testing. In: ASM handbook. Materials Park, OH: ASM International, 2003, http://www2.asminternational.org/content/ASM/StoreFiles/06494G_Frontmatter.pdf

Rathod

Roy

Gopalakrishnan

. Lamb wave based identification and parameter estimation of corrosion in metallic plate structure using a circular PWAS array. In: Proceedings of the 16th SPIE annual symposium on smart structures and materials, San Diego, California, March 9–12, 2009, vol. 7295.

Steven

. Sensor technology innovation for the advancement of structural health monitoring: a strategic program of US-China research for the next decade. Smart Struct Syst2007; 3: 221–244.

Qiao

Zhou

. Thin Fe-C alloy solid film based fiber optic corrosion sensor. In: Proceedings of the 1st IEEE conference on nano/micro engineered and molecular systems, Zhuhai, China, 18–21 January 2006, pp. 541–544. New York: IEEE.

Christopher

Kai

Chen

. A novel optical fiber sensor for steel corrosion in concrete structures. Sensors2008; 8: 1960–1976.

Wade

Wallbrink

McAdam

. A fiber optic corrosion fuse sensor using stressed metal-coated optical fibers. Sensor Actuat B: Chem2008; 131: 602–608.

10.

Qiao

. Corrosion monitoring of reinforcing steel in cement mortar by EIS and ENA. Electrochim Acta2007; 52: 8008–8019.

11.

Dickerson

Wood

. Wireless low-cost corrosion sensors for reinforced concrete structure. In: Proceedings of the 12th SPIE annual symposium on smart structures and materials, San Diego, California, March 6–10, 2005, vol. 5765, pp. 493–503. SPIE.

12.

Agarwala

Ahmad

. Corrosion detection and monitoring—a review. In: Proceedings of the NACE international, Orlando, Florida, March 26–31, 2000, paper no. 271.

13.

Dong

Peng

Luo

. Preparation techniques of metal clad fibers for corrosion monitoring of steel materials. Smar Mat St2007; 16: 733–738.

14.

Abderrahmane

Himour

Kherrat

. An optical fiber corrosion sensor with an electroless deposit of Ni–P. Sensor Actuat B: Chem2001; 75: 1–4.

15.

Benounis

Jaffrezic-Renault

. Elaboration of an optical fiber corrosion sensor for aircraft applications. Sensor Actuat B: Chem2004; 100: 1–8.

16.

Zheng

Sun

Lei

. Monitoring corrosion of reinforcement in concrete structures via fiber Bragg grating sensors. Front Mech Eng China2009; 4(3): 316–319.

17.

Hua

Cai

Yang

. Fe-C-coated fibre Bragg grating sensor for steel corrosion monitoring. Corros Sci2010; 53: 1933–1938.

18.

Cooper

Elster

Jones

. Optical fiber-based corrosion sensor systems for health monitoring of aging aircraft. In: Proceedings of the IEEE Systems Readiness Technology Conference, Valley Forge, Pennsylvania, August 20–23, 2001, pp. 847–856. IEEE.

19.

Bhatia

Vengsarkar

. Optical fiber long period grating sensor. Opt Lett1996; 21: 692–694.

20.

Shu

Zhang

Bennion

. Sensitivity characteristics of long-period fiber gratings. J Lightwave Technol2002; 20(2): 255–266.

21.

Wei

Montoya

. Measurement of CO₂ laser irradiation induced refractive index modulation in single mode fiber towards LPFG design and fabrication. Appl Optics2008; 47: 5296–5304.

22.

Montemor

Simões

AMP

Ferreira

MGS

. Chloride-induced corrosion on reinforcing steel: from the fundamentals to the monitoring techniques. Cement Concrete Comp2003; 25: 491–502.

23.

McCafferty

. Validation of corrosion rates measured by the Tafel extrapolation method. Corros Sci2005; 47: 3202–3215.

24.

Chen

. Structural health monitoring in civil infrastructure applications: new perspectives. In: Proceedings of the 5th international conference on structural health monitoring of intelligent infrastructures, Cancún, México, 11–15 December 2011.

Steel bar corrosion monitoring with long-period fiber grating sensors coated with nano iron/silica particles and polyurethane

Abstract

Keywords

Get full access to this article

References