Structural health monitoring has become a viable solution to monitor critical infrastructure components that show distress or are unable to pass current load ratings. This research introduces the concept of a composite layer bonded to concrete structures, which is capable of providing distributed sensing capabilities. The layer consists of carbon nanotubes that are deposited on a carrier, which form a continuous conductive skin that is exceptionally sensitive to changes in strain and the formation and propagation of micro-damage and macro-damage. It can be either structural, where the layer represents the reinforcement as well as the sensor, or nonstructural, where the layer acts as a sensing skin alone. Distributed sensing allows for increased detectability of forming or growing damage that cannot necessarily be captured with conventional point-type sensors such as strain gages or accelerometers. Once developed, this sensing skin may be able to give real-time feedback on changes in strain, temperature effects, and formation and propagation of damage. In this article, we present the fabrication and evaluation of an integrated structural sensing composite layer attached to a concrete beam specimen. The specimen was tested to failure in the laboratory. Experimental results are presented and discussed, and currently ongoing research is introduced.
American Society of Civil Engineers (ASCE) (2010) Report card for America’s infrastructure. Available at: http://www.infrastructurereportcard.org/ (accessed 11 March 2010).
2.
ArndtRWSchumacherTAlgernonD. (2011) Strategies for maintenance of highway bridges in the US—with the support of non-destructive testing and structural health monitoring. Bautechnik88(11): 793–804.
3.
BakisCENanniATeroskyJA. (2001) Self-monitoring, pseudo-ductile, hybrid FRP reinforcement rods for concrete applications. Composites Science and Technology61(6): 815–823.
4.
BakisCEBankLCBrownVL. (2002) Fiber-reinforced polymer composites for construction—state-of-the-art review. Journal of Composites for Construction6(2): 73–87.
5.
ChouT-WGaoLMThostensonET. (2010) As assessment of the science and technology of carbon nanotube fibers and composites. Composites Science and Technology70(1): 1–19.
6.
DharapPLiZNagarajaiahS. (2004) Flexural strain sensing using carbon nanotube film. Sensor Review24(3): 271–273.
7.
EnckellMGlisicBMyrvollF. (2011) Evaluation of a large-scale bridge strain, temperature and crack monitoring with distributed fibre optic sensors. Journal of Civil Structural Health Monitoring1(1–2): 37–46.
8.
GaoLMChouT-WThostensonET. (2010a) A comparative study of damage sensing in fiber composites using uniformly and non-uniformly dispersed carbon nanotubes. Carbon48(13): 3788–3794.
9.
GaoLMChouT-WThostensonET. (2010c) Highly conductive polymer composites based on controlled agglomeration of carbon nanotubes. Carbon48(9): 2649–2651.
10.
GaoLMChouT-WThostensonET. (2011) In situ sensing of impact damage in epoxy/glass fiber composites using percolating carbon nanotube networks. Carbon49(10): 3382–3385.
11.
GaoLMThostensonETZhangZG. (2009a) Coupled carbon nanotube network and acoustic emission monitoring for sensing of damage development in composites. Carbon47(5): 1381–1388.
12.
GaoLMThostensonETZhangZG. (2009b) Sensing of damage mechanisms in fiber-reinforced composites under cyclic loading using carbon nanotubes. Advanced Functional Materials19(1): 123–130.
13.
GaoLMThostensonETZhangZG. (2010b) Damage monitoring in fiber-reinforced composites under fatigue loading using carbon nanotube networks. Philosophical Magazine90(31–32): 4085–4099.
14.
GlisicBInaudiD (2010) Distributed fiber-optic sensing and integrity monitoring. Transportation Research Record: Journal of the Transportation Research Board2150: 96–102.
15.
GlisicBInaudiD (2012) Development of method for in-service crack detection based on distributed fiber optic sensors. Structural Health Monitoring11(2): 161–171.
16.
HouT-CLynchJP (2009) Electrical impedance tomographic methods for sensing strain fields and crack damage in cementitious structures. Journal of Intelligent Material Systems and Structures20(11): 1363–1379.
17.
KangISchulzMJKimJH. (2006) A carbon nanotube strain sensor for structural health monitoring. Smart Materials and Structures15(3): 737–748.
18.
KimKJYuWRLeeJS. (2010) Damage characterization of 3D braided composites using carbon nanotubes-based in situ sensing. Composites Part A: Applied Science and Manufacturing41(10): 1531–1537.
19.
LiCYThostensonETChouTW (2007) Dominant role of tunneling resistance in the electrical conductivity of carbon nanotube-based composites. Applied Physics Letters91(22): 223114-1–223114-3.
20.
LiCYThostensonETChouTW (2008) Sensors and actuators based on carbon nanotubes and their composites: a review. Composites Science and Technology68(6): 1227–1249.
21.
LimASAnQChouTW. (2011a) Mechanical and electrical response of carbon nanotube-based fabric composites to Hopkinson bar loading. Composites Science and Technology71(5): 616–621.
22.
LimASMelroseZRThostensonET. (2011b) Damage sensing of adhesively-bonded hybrid composite/steel joints using carbon nanotubes. Composites Science and Technology71(9): 1183–1189.
23.
LohKJHouTCLynchJP. (2007) Nanotube-based sensing skins for crack detection and impact monitoring of structures. In: Proceedings of 6th international workshop on structural health monitoring, 11-13 September 2007. Stanford, CA.
24.
NanniFRuscitoGNadL. (2009) Self-sensing nanocomposite CnP–GFRP rods as reinforcement and sensors of concrete beams. Journal of Intelligent Material Systems and Structures20(13): 1615–1623.
25.
NCHRP (2004) Bonded repair and retrofit of concrete structures using FRP composites. NCHRP Report 514, Washington, DC: Transportation Research Board.
26.
RakiLBeaudoinJAlizadehR. (2010) Cement and concrete nanoscience and nanotechnology. Materials3(2): 918–942.
27.
SaafiM (2009) Wireless and embedded carbon nanotube networks for damage detection in concrete structures. Nanotechnology20(39): 395502.
28.
SchumacherT (2008) Acoustic emission techniques applied to conventionally reinforced concrete bridge girders. Research Report SPR 633, Salem, September. OR: Oregon Department of Transportation.
29.
SchumacherTHigginsCCLovejoySC (2011) Estimating operating load conditions on reinforced concrete highway bridges with b-value analysis from acoustic emission monitoring. Structural Health Monitoring10(1): 17–32.
30.
ThostensonETChouT-W (2001) Advances in the science and technology of carbon nanotubes and their composites: a review. Composites Science and Technology61(13): 1899–1912.
31.
ThostensonETChouT-W (2006a) Carbon nanotube networks: sensing of distributed strain and damage for life prediction and self-healing. Advanced Materials18(22): 2837–2841.
ThostensonETChouT-W (2008a) Carbon nanotube-based health monitoring of mechanically fastened composite joints. Composites Science and Technology68(12): 2557–2561.
34.
ThostensonETChouT-W (2008b) Real-time in situ sensing of damage evolution in advanced fiber composites using carbon nanotube networks. Nanotechnology19(21): 215713.
35.
ThostensonETLiCYChouTW (2005) Nanocomposites in context. Composites Science and Technology65(3–4): 491–516.
36.
ThostensonETZiaeeSChouTW (2009) Processing and electrical properties of carbon nanotube/vinyl ester nanocomposites. Composites Science and Technology69(6): 801–804.
37.
XiaoHLiHOuJ (2011) Self-monitoring properties of concrete columns with embedded cement-based strain sensors. Journal of Intelligent Material Systems and Structures22(2): 191–200.
38.
YangCQWuZS (2006) Self-structural health monitoring function of RC structures with HCFRP sensors. Journal of Intelligent Material Systems and Structures17(10): 895–906.
39.
ZhangBZhouZZhangK. (2006) Sensitive skin and the relative sensing system for real-time surface monitoring of crack in civil infrastructure. Journal of Intelligent Material Systems and Structures17(10): 907–917.
40.
ZhaoMMGongYZhaoY. (2007) Monitoring of bond in FRP retrofitted concrete structures. Journal of Intelligent Material Systems and Structures18(8): 853–860.
