Development and application of long-term in situ monitoring system for complex deep-sea engineering geology

doi:10.13745/j.esf.sf.2021.9.15

Abstract

Abstract:

Geohazards such as submarine landslides and turbidity currents are an urgent safety issue to be solved in marine engineering during national deep sea development. To avoid such risks and achieve geohazard monitory and early warning, we develop an in-situ monitory system for complex deepwater engineering geology (SEEGeo), using resistivity, acoustic and pore pressure monitoring to monitor the physical and mechanical changes in deep seabed sediments. This monitoring system mainly includes the seabed carrying platform, monitoring system, communication control system, and power supply system. The monitoring system performs long-term in-situ monitoring of resistivity, acoustic and pore pressure changes in seabed sediments; the communication control system is responsible for communication and data transmission from seabed to sea surface then to land; and the power supply system provides power for one year of long-term operation on the seabed via an unique seawater battery process. So far, SEEGeo has completed the offshore test and carried out multiple sea trials in the South China Sea on board scientific research ships (e.g., “Marine Geology No. 6”, “Dongfanghong No. 3”, “Zhang Jian”), and collected large amounts of survey data. For example, using Wenner method, resistivity monitoring obtained an average resistivity of 0.207 Ω·m at the water-soil interface location. Super excess pore pressure monitoring, using open-structured optical fiber-based differential pressure sensing, observed four landmark stages: 1) pressure accumulation during penetration (up to 34.942 kPa over 0.182 h); 2) pressure decay after penetration (down to 9.973 kPa over 0.810 h); 3) real-time response to environmental stress (pressure change between 8.327-14.384 kPa); and 4) residual pressure (average 11.150 kPa). And acoustic monitoring, adopting two sets of one transmit-three receive setup, obtained a seawater average sound velocity of 1 533 m/s, as well as average sound velocities of 1 586, 1 587, 1 784, 1 735 and 1 831 m/s in seafloor sediments from the top to the bottom layers. The successful development of SEEGeo will significantly improve the current technical capabilities for long-term in-situ marine engineering geology monitoring, complex engineering geology evaluation and geohazard monitoring and early warning.

Key words: natural submarine geohazards, physical and mechanical properties, in-situ monitoring, sound speed, resistivity, pore pressure

CLC Number:

SUN Zhiwen, JIA Yonggang, QUAN Yongzheng, GUO Xiujun, LIU Tao, MENG Qingsheng, SUN Zhongqiang, LI Kai, FAN Zhihan, CHEN Tian, TANG Haoru. Development and application of long-term in situ monitoring system for complex deep-sea engineering geology[J]. Earth Science Frontiers, 2022, 29(5): 216-228.

Figures/Tables 15

Fig.1 The working pattern diagram of the in-situ Surveying Equipment of Engineering Geology (SEEGeo) in complex deep sea

Fig.2 The photograph of SEEGeo

Fig.3 Schematic diagram and photograph of acoustic monitoring system

Fig.4 Schematic diagram and photograph of resistivity monitoring system

Fig.5 The pore pressure monitoring system

Fig.6 Marine hydrodynamic long-term monitoring system

Fig.7 Integrated sea-air-land data real-time communication system

Fig.8 The control structure and remote control software of the main control system

Fig.9 The schematic diagram and photograph of seawater battery

Fig.10 The offshore sea trial and the South China Sea trial of SEEGeo

Fig.11 Single resistivity monitoring data and multiple resistivity data monitoring cloud

Fig.12 Long-term monitoring curve of excess pore water pressure in seafloor sediments

Fig.13 The six channel acoustic wave data of seabed sediments

Fig.14 Six channel sound velocity of seabed sediment

Table 1 Summary of six channel sound velocity of seafloor sediments

接收通道	声速/(m·s^-1)			方差值
接收通道	最小值	最大值	平均值	方差值
CH1	1 516	1 560	1 533	145
CH2	1 561	1 614	1 586	404
CH3	1 567	1 598	1 587	51
CH4	1 656	1 830	1 784	1 253
CH5	1 607	1 803	1 735	1 052
CH6	1 641	1 897	1 831	2 108

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