[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sss.2010.6.5_6.731

Concrete structural health monitoring using piezoceramic-based wireless sensor networks

Li, Peng (Department of Mechanical Engineering, University of Houston)
Gu, Haichang (Department of Mechanical Engineering, University of Houston)
Song, Gangbing (Department of Mechanical Engineering, University of Houston)
Zheng, Rong (Department of Computer Science, University of Houston)
Mo, Y.L. (Department of Civil and Environmental Engineering, University of Houston)

Publication Information

Smart Structures and Systems / v.6, no.5_6, 2010 , pp. 731-748 More about this Journal

Abstract

Impact detection and health monitoring are very important tasks for civil infrastructures, such as bridges. Piezoceramic based transducers are widely researched for these tasks due to the piezoceramic material's inherent advantages of dual sensing and actuation ability, which enables the active sensing method for structural health monitoring with a network of piezoceramic transducers. Wireless sensor networks, which are easy for deployment, have great potential in health monitoring systems for large civil infrastructures to identify early-age damages. However, most commercial wireless sensor networks are general purpose and may not be optimized for a network of piezoceramic based transducers. Wireless networks of piezoceramic transducers for active sensing have special requirements, such as relatively high sampling rate (at a few-thousand Hz), incorporation of an amplifier for the piezoceramic element for actuation, and low energy consumption for actuation. In this paper, a wireless network is specially designed for piezoceramic transducers to implement impact detection and active sensing for structural health monitoring. A power efficient embedded system is designed to form the wireless sensor network that is capable of high sampling rate. A 32 bit RISC wireless microcontroller is chosen as the main processor. Detailed design of the hardware system and software system of the wireless sensor network is presented in this paper. To verify the functionality of the wireless sensor network, it is deployed on a two-story concrete frame with embedded piezoceramic transducers, and the active sensing property of piezoceramic material is used to detect the damage in the structure. Experimental results show that the wireless sensor network can effectively implement active sensing and impact detection with high sampling rate while maintaining low power consumption by performing offline data processing and minimizing wireless communication.

Keywords

wireless sensor network; impact detection; structural health monitoring; embedded system; piezoceramic sensor;

Citations & Related Records

Reference

1	Avancha, S., Patel, C. and Joshi, A. (2004), "Ontology-driven adaptive sensor networks", Proceedings of the First Annual International Conference on Mobile and Ubiquitous Systems: Networking and Services.
2	Bahel-el-din, Y.A., Saleh, A.M. and Talaat, M.M. (2003), "Electromechanical impedance technique for health monitoring of concrete structures", J. Eng. Appl. Sci., 50, 1111-1124.
3	Bernard, R.T., Galen, K.B., Joseph, R.C., Henry, A.A., Siamak, S., Brian, A.K. and Hans, R.Z. (1988), Impact detection apparatus, United States Patent, 4745564.
4	Champaigne, K.D. and Sumner, J. (2007), "Low-power electronics for distributed impact detection and piezoelectric sensor applications", Proceedings of the IEEE Aerospace Conference.
5	Dubois-Ferriere, H., Meier, R., Fabre, L. and Metrailler, P. (2006), TinyNode: a comprehensive platform for wireless sensornetwork applications", Proceedings of the '06 Information Processing in Sensor Networks, Nashville, Tennessee, USA, April.
6	Farrar, C. and Worden, K. (2007), "An introduction to structural health monitoring", Phil. Trans. R. Soc. A, 365(1851), 303-315. DOI ScienceOn
7	Fujii, Y. and Fujimoto, H. (1999), "Proposal for an impulse response evaluation method for force transducers", Meas. Sci. Technol., 10(4), N31-N33. DOI ScienceOn
8	Gu, H., Song, G., Dhonde, H., Mo, Y.L. and Yan, S. (2006), "Concrete early-age strength monitoring using embedded piezoelectric transducers", Smart Mater. Struct., 15, 1837-1845. DOI ScienceOn
9	Hill, J., Szewczyk, R., Woo, A., Hollar, S., Culler, D. and Pister, K. (2000), "System architecture directions for networked sensors", ACM SIGPLAN Notices, 35(11), 93-104. DOI
10	Laskar, A., Gu, H., Mo, Y.L. and Song, G. (2009), "Progressive collapse of a 2-story reinforced concrete frame with embedded smart aggregate", Smart Mater. Struct., 18(7).
11	Liao, W.I., Gu, H., Olmi, C., Song, G., Mo, Y.L. and Loh, C.H. (2008), "Structural health monitoring of a concrete column subjected to shake table excitations using smart aggregates", Proceedings of the Intelligent Sensor and Actuator Symposium at ASCE Earth and Space conference, Long Beach, California, March.
12	Mechitov, K., Kim, W., Agha, G. and Nagayama, T. (2004), "High-frequency distributed sensing for structure monitoring", Proceedings of the First International Workshop on Networked Sensing Systems.
13	Mevel, L., Hermans, L. and van der Auweraer, H. (2000), "Health monitoring of a concrete three-span bridge", Proc. SPIE-The Int. Soc. Opt. Eng., 4062, 690-694.
14	Olmi, C., Song, G. and Mo, Y.L. (2009), "Develop a mini-scale amplifier for piezoceramic active sensing devices for civil structural health monitoring", Proceedings of the International Postgraduate Conference on Infrastructure and Environment, Hong Kong, China.
15	Pottie, G.J. and Kaiser, W.J. (2000), "Wireless integrated network sensors", Commun. ACM, 43(5), 51-58. DOI ScienceOn
16	Song, G., Gu, H., Mo, Y.L., Hsu, T., Dhonde, H. and Zhu, R.R.H. (2005), "Health monitoring of a concrete structure using piezoceramic materials", Proc. SPIE-The Int. Soc. Opt. Eng., 5765, 108-119 (Part 1: Smart Structures and Materials).
17	Song, G., Gu, H. and Mo, Y.L. (2007a), "Smart aggregates: a distributed intelligent multi-purpose sensor network (DIMSN) for civil structures", Proceedings of the 2007 IEEE International Conference on Networking, Sensing and Control.
18	Song, G., Gu, H., Mo, Y.L., Hsu, T.T.C. and Dhonde, H. (2007b), "Concrete structural health monitoring using embedded piezoceramic transducers", Smart Mater. Struct., 16(4), 959-968. DOI ScienceOn
19	Song, G., Olmi, C. and Gu, H. (2007c), "An overheight vehicle-bridge collision monitoring system using piezoelectric transducers", Smart Mater. Struct., 16, 462-468. DOI ScienceOn
20	Song, G., Gu, H. and Mo, Y.L. (2008), "Smart aggregates: multi-functional sensors for concrete structures - a tutorial and a review", Smart Mater. Struct., 17(3).
21	Staszewski, W.J., Worden, K., Wardle, R. and Tomlinson, G.R. (2000), "Fail-safe sensor distributions for impact detection in composite materials", Smart Mater. Struct., 9(3), 298-303. DOI ScienceOn
22	Tseng, K.K. and Wang, L. (2004), "Smart piezoelectric transducers for in situ health monitoring of concrete", Smart Mater. Struct., 13, 1017-1024. DOI ScienceOn
23	Viscardi, M. and Lecce, L. (2002), "An integrated system for active vibro-acoustic control and damage detection on a typical aeronautical structure", Proceedings of the 2002 International Conference on Control Applications.
24	Wu, J., Yuan, S., Zhao, X., Yin, Y. and Ye, W. (2007), "A wireless sensor networks node designed for exploring a structural health monitoring application", Smart Mater. Struct., 16( 5), 1898-1906. DOI ScienceOn
25	Yan, S., Sun, W., Song, G., Gu, H., Huo, L.S., Liu, B. and Zhang, Y.G. (2009), "Health monitoring of reinforced concrete shear walls using smart aggregates", Smart Mater. Struct., 18(4).
26	Yang, Y.C. and Han, K.S. (2002), "Damage monitoring and impact detection using optical fiber vibration sensors", Smart Mater. Struct., 11(3), 337-345. DOI ScienceOn

Reference

1	Qing Ji. (2015) Smart Structures and Systems An exploratory study of stress wave communication in concrete structures / 15 (1) , 135
12	Y. Lei. (2012) International Journal of Distributed Sensor Networks Intelligent Monitoring of Multistory Buildings under Unknown Earthquake Excitation by a Wireless Sensor Network / 8 (12) , 914638
05	Guang-Dong Zhou. (2014) International Journal of Structural Stability and Dynamics Wireless Sensor Placement for Bridge Health Monitoring Using a Generalized Genetic Algorithm / 14 (05) , 1440011
6	R.B. Bai. (2014) Smart Structures and Systems Crack location in beams by data fusion of fractal dimension features of laser-measured operating deflection shapes / 13 (6) , 975
4	A. Diaz Lantada. (2014) Smart Structures and Systems Combining smart materials for enhancing intelligent systems: initial studies, success cases and research trends / 14 (4) , 517
4	Yongfeng Fang. (2014) Smart Structures and Systems Reliability analysis of repairable k-out-n system from time response under several times stochastic shocks / 14 (4) , 559
12	Heyue Yin. (2016) Applied Sciences A Smart Washer for Bolt Looseness Monitoring Based on Piezoelectric Active Sensing Method / 6 (12) , 320
13	Jianjun Wang. (2013) Journal of Intelligent Material Systems and Structures Analytical solution of piezoelectric composite stack transducers / 24 (13) , 1626
4	R L Wang. (2013) Smart Materials and Structures Proof-of-concept experimental study of damage detection of concrete piles using embedded piezoceramic transducers / 22 (4) , 042001
10	Jianjun Wang. (2015) Smart Materials and Structures Modeling on energy harvesting from a railway system using piezoelectric transducers / 24 (10) , 105017
1	Zhifei Shi. (2013) Journal of Intelligent Material Systems and Structures Dynamic analysis of 2-2 cement–based piezoelectric transducers / 24 (1) , 99
4	Jianjun Wang. (2016) Journal of Intelligent Material Systems and Structures Models for designing radially polarized multilayer piezoelectric/elastic composite cylindrical transducers / 27 (4) , 500
10	Jianjun Wang. (2013) IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control Dynamic characteristics of an axially polarized multilayer piezoelectric/elastic composite cylindrical transducer / 60 (10) , 2196
11	Wen-ai Shen. (2012) International Journal of Distributed Sensor Networks Feasibility of Output-Only Modal Identification Using Wireless Sensor Network: A Quantitative Field Experimental Study / 8 (11) , 560161
19	Qing Ji. (2017) Journal of Intelligent Material Systems and Structures Wireless energy harvesting using time reversal technique: An experimental study with numerical verification / 28 (19) , 2705
7	Shi Yan. (2017) Sensors Development and Application of a Structural Health Monitoring System Based on Wireless Smart Aggregates / 17 (7) , 1641
	Jian Chen. (2018) International Journal of Structural Stability and Dynamics Feedback Control for Structural Health Monitoring in a Smart Aggregate Based Sensor Network / , 1850064
11	Peng Li. (2014) IEEE Transactions on Cybernetics Wireless Sensing and Vibration Control With Increased Redundancy and Robustness Design / 44 (11) , 2076
8	Jianjun Wang. (2013) IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control Electromechanical analysis of piezoelectric beam-type transducers with interlayer slip / 60 (8) , 1768
20	Jianjun Wang. (2017) Journal of Intelligent Material Systems and Structures Theoretical analysis of a resistance adjusting type piezoelectric cylindrical transducer / 28 (20) , 2896
10	Guofeng Du. (2013) International Journal of Distributed Sensor Networks Feasibility Study on Crack Detection of Pipelines Using Piezoceramic Transducers / 9 (10) , 631715
3	Jianjun Wang. (2014) Smart Structures and Systems Electromechanical analysis of 2-2 cement-based piezoelectric transducers in series electrically / 14 (3) , 267
6	Kanjuro Makihara. (2015) Smart Structures and Systems Self-reliant wireless health monitoring based on tuned-mass-damper mechanism / 15 (6) , 1625
12	Taotao Zhang. (2015) Micromachines Analysis of Dynamic Properties of Piezoelectric Structure under Impact Load / 6 (12) , 1577
4	(2019) Applied Sciences Hysteretic Behavior of Steel Reinforced Concrete Columns Based on Damage Analysis / 9 (4) , 687
3	(2020) Journal of low frequency noise, vibration, and active control Design and validation of a fast wireless low-frequency vibration inspection system for offshore platform structures / 39 (3) , 720
2234-991X	(2012) Advanced Engineering Forum Carbon Fibre/Silicon Composite Sensors for Concrete Structural Health Monitoring in Compression / 5 (2234-991X) , 224
4	(2018) Sensors Development and Hybrid Position/Force Control of a Dual-Drive Macro-Fiber-Composite Microgripper / 18 (4) , 1301
3	(2010) Smart structures and systems Strain monitoring of reinforced concrete with OTDR-based FBG interrogation technique / 20 (3) , 343
9	(2010) Applied sciences Mechanical Properties of Desert Sand-Based Fiber Reinforced Concrete (DS-FRC) / 9 (9) , 1857
6	(2010) Structural health monitoring Design of a new low-cost unmanned aerial vehicle and vision-based concrete crack inspection method / 19 (6) , 1871

1	Crack location in beams by data fusion of fractal dimension features of laser-measured operating deflection shapes / [Bai, R.B.;Song, X.G.;Radzienski, M.;Cao, M.S.;Ostachowicz, W.;Wang, S.S.;] / Smart Structures and Systems
2	Electromechanical analysis of 2-2 cement-based piezoelectric transducers in series electrically / [Wang, Jianjun;Shi, Zhifei;] / Smart Structures and Systems
3	Reliability analysis of repairable k-out-n system from time response under several times stochastic shocks / [Fang, Yongfeng;Tao, Wenliang;Tee, Kong Fah;] / Smart Structures and Systems
4	Combining smart materials for enhancing intelligent systems: initial studies, success cases and research trends / [Diaz Lantada, A.;Lafont Morgado, P.;Munoz-Guijosa, J.M.;Munoz Sanz, J.L.;Echavarri Otero, J.;Chacon Tanarro, E.;De la Guerra Ochoa, E.;] / Smart Structures and Systems