NH13B-1921
Development of IoT-based Urban Sinkhole and Road Collapse Monitoring System

Monday, 14 December 2015
Poster Hall (Moscone South)
Byeongju Jung1,2, Eunseok Bang1,2, Hong-Jin Lee1,2, Sueng Won Jeong1,2, Sung Woung Kim1,2, Dongwoo Ryu1,2, Byoung-Woo Yum1,2 and In-Hwan Lee2, (1)KIGAM Korea Institute of Geoscience and Mineral Resources, Geological Environment Division, Daejeon, South Korea, (2)ETRI Electrconics and Telecommunications Research Institute, UGS Convergence Research Group, Daejeon, South Korea
Abstract:
The consortium of Korean government-funded research institutes is developing IoT- (Internet of things) based underground safety monitoring and alerting system to manage risks arisen from land subsidence and road collapses in metropolitan areas in South Korea. The system consists of four major functional units: subsurface monitoring sensors sending data directly through the internet, centralized servers capable of collecting and processing big data, computational modules providing physical and statistical models for predicting high-risk areas, and geologic information service platforms visualizing underground safety maps for the public.

The target urban area will be regionally covered by multi-sensors monitoring soil and groundwater conditions, and by high resolution satellite InSAR images filtering vertical land movements in a centimeter scale. Integrity of buried water supply and sewer lines are also monitored for the possibility of underground cavity formation. Once high-risk area is predicted, more tangible surveying methods such as ground penetrating radar (GPR) and resistivity survey can be applied for locating the cavities.

Additionally, laboratory and field experiments are performed to understand overall road collapsing mechanism from the initial cavity creation to its progressive development depending on soil types, degree of compaction, and groundwater condition. Acquired results will update existing fully-coupled hydromechanical models for more accurate prediction of the collapsing-vulnerable area. Preliminary laboratory experiments show that the upward propagation of subsurface cavity is closely related to the soil properties, such as sand-clay ratios and moisture contents, and groundwater dynamics.