TY - GEN
T1 - Empowering smart buildings with self-sensing concrete for structural health monitoring
AU - Gong, Zheng
AU - Han, Lubing
AU - An, Zhenlin
AU - Yang, Lei
AU - Ding, Siqi
AU - Xiang, Yu
N1 - Funding Information:
We thank all anonymous reviewers for the insightful feedback. This study is supported by NSFC Excellent Young Scientists Fund (Hong Kong and Macau) (No. 62022003), NSFC Key Program (No. 61932017), NSFC General Program (No. 61972331), UGC/GRF (No. 15204820, 15215421), and National Key R&D Program of China 2019YFB2103000. Zhenlin An and Lei Yang are the co-corresponding authors.
Publisher Copyright:
© 2022 ACM.
PY - 2022/8/22
Y1 - 2022/8/22
N2 - Given the increasing number of building collapse tragedies nowadays (e.g., Florida condo collapse), people gradually recognize that long-Term and persistent structural health monitoring (SHM) becomes indispensable for civilian buildings. However, current SHM techniques suffer from high cost and deployment difficulty caused by the wired connection. Traditional wireless sensor networks fail to serve in-concrete communication for SHM because of the complexity of battery replacement and the concrete Faraday cage. In this work, we collaborate with experts from civil engineering to create a type of promising self-sensing concrete by introducing a novel functional filler, called EcoCapsule-a battery-free and miniature piezoelectric backscatter node. We overcome the fundamental challenges in in-concrete energy harvesting and wireless communication to achieve SHM via EcoCapsules. We prototype EcoCapsules and mix them with other raw materials (such as cement, sand, water, etc) to cast the self-sensing concrete, into which EcoCapsules are implanted permanently. We tested EcoCapsules regarding real-world buildings comprehensively. Our results demonstrate single link throughputs of up to 13 kbps and power-up ranges of up to 6 m. Finally, we demonstrate a long-Term pilot study on the structural health monitoring of a real-life footbridge.
AB - Given the increasing number of building collapse tragedies nowadays (e.g., Florida condo collapse), people gradually recognize that long-Term and persistent structural health monitoring (SHM) becomes indispensable for civilian buildings. However, current SHM techniques suffer from high cost and deployment difficulty caused by the wired connection. Traditional wireless sensor networks fail to serve in-concrete communication for SHM because of the complexity of battery replacement and the concrete Faraday cage. In this work, we collaborate with experts from civil engineering to create a type of promising self-sensing concrete by introducing a novel functional filler, called EcoCapsule-a battery-free and miniature piezoelectric backscatter node. We overcome the fundamental challenges in in-concrete energy harvesting and wireless communication to achieve SHM via EcoCapsules. We prototype EcoCapsules and mix them with other raw materials (such as cement, sand, water, etc) to cast the self-sensing concrete, into which EcoCapsules are implanted permanently. We tested EcoCapsules regarding real-world buildings comprehensively. Our results demonstrate single link throughputs of up to 13 kbps and power-up ranges of up to 6 m. Finally, we demonstrate a long-Term pilot study on the structural health monitoring of a real-life footbridge.
KW - backscatter communication
KW - structural health monitoring
KW - ultrasonics
UR - http://www.scopus.com/inward/record.url?scp=85138054698&partnerID=8YFLogxK
U2 - 10.1145/3544216.3544270
DO - 10.1145/3544216.3544270
M3 - Conference article published in proceeding or book
AN - SCOPUS:85138054698
T3 - SIGCOMM 2022 - Proceedings of the ACM SIGCOMM 2022 Conference
SP - 560
EP - 573
BT - SIGCOMM 2022 - Proceedings of the ACM SIGCOMM 2022 Conference
PB - Association for Computing Machinery, Inc
T2 - 2022 Conference of the ACM Special Interest Group on Data Communication, SIGCOMM 2022
Y2 - 22 August 2022 through 26 August 2022
ER -