Deep sea mud volcano in-situ monitoring system and method

A monitoring system and mud volcano technology, applied in the field of deep sea mud volcano in-situ monitoring system, can solve problems such as the cost of using ships, reduce the number of times and time, and facilitate research and data analysis.

Pending Publication Date: 2021-11-05
GUANGZHOU MARINE GEOLOGICAL SURVEY
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0003] In order to overcome the deficiencies of the prior art, one of the objectives of the present invention is to provide a deep-sea mud volcano in-situ monitoring system, which can solve the problem of using ships to monitor deep-sea mud volcanoes and cause excessive costs
[0004] In order to overcome the deficiencies in the prior art, the second object of the present invention is to provide a method for in-situ monitoring of deep-sea mud volcanoes, which can solve the problem that ships must be used to monitor deep-sea mud volcanoes and the cost is too high

Method used

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  • Deep sea mud volcano in-situ monitoring system and method
  • Deep sea mud volcano in-situ monitoring system and method
  • Deep sea mud volcano in-situ monitoring system and method

Examples

Experimental program
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Effect test

Embodiment 1

[0036] like Figure 1-2 As shown, a deep-sea mud volcano in-situ monitoring system includes a guiding mechanism 1 for forming a monitoring path and a monitoring mechanism 2 for periodically monitoring mud volcanoes along the monitoring path. The monitoring mechanism 2 includes a frame, for The data acquisition module 21 for processing the monitoring data, the monitoring component 22 for monitoring the mud volcano and the navigation component 23 for guiding the monitoring mechanism 2 to move along the monitoring path, the data acquisition module 21, the monitoring component 22 and the navigation component 23 are all arranged in On the rack, both the monitoring component 22 and the navigation component 23 are connected to the data collection cabin 21 , and the guide mechanism 1 is connected to the navigation component 23 . Preferably, the monitoring component 22 includes monitoring devices such as multi-beam sonar, methane sensor and temperature sensor, and the multi-beam sonar,...

Embodiment 2

[0040] like image 3 As shown, a deep-sea mud volcano in-situ monitoring system includes a guiding mechanism 1 for forming a monitoring path and a monitoring mechanism 2 for periodically monitoring mud volcanoes along the monitoring path. The monitoring mechanism 2 includes a frame, for The data acquisition module 21 for processing the monitoring data, the monitoring component 22 for monitoring the mud volcano and the navigation component 23 for guiding the monitoring mechanism 2 to move along the monitoring path, the data acquisition module 21, the monitoring component 22 and the navigation component 23 are all arranged in On the rack, both the monitoring component 22 and the navigation component 23 are connected to the data collection cabin 21 , and the guide mechanism 1 is connected to the navigation component 23 . Preferably, the monitoring component 22 includes monitoring devices such as multi-beam sonar, methane sensor and temperature sensor, and the multi-beam sonar, me...

Embodiment 3

[0043] A deep-sea mud volcano in-situ monitoring method, the method includes a data acquisition cabin applied to the deep-sea mud volcano in-situ monitoring system, the deep-sea mud volcano in-situ monitoring system includes a monitoring path 1 for forming a monitoring path and a monitoring path for monitoring along the A monitoring mechanism for periodically monitoring mud volcanoes, the monitoring mechanism includes a frame, a data acquisition cabin 21 for processing monitoring data, a monitoring component 22 for monitoring mud volcanoes, and a navigation device for guiding the monitoring mechanism to move along the monitoring path Component 23, the data collection cabin 21, the monitoring component 22 and the navigation component 23 are all arranged on the frame, the monitoring component 22 and the navigation component 23 are all connected with the data collection cabin 21, and the monitoring path 1 and the navigation component 23 Connection; the monitoring path 1 includes s...

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Abstract

The invention discloses a deep sea mud volcano in-situ monitoring system and method. The system comprises a guiding mechanism which is used for forming a monitoring path, and a monitoring mechanism which is used for carrying out the periodic monitoring of a mud volcano along the monitoring path. The monitoring mechanism comprises a rack, a data acquisition cabin used for processing monitoring data, a monitoring assembly used for monitoring the mud volcano and a navigation assembly used for guiding the monitoring mechanism to move along a monitoring path, and the data acquisition cabin, the monitoring assembly and the navigation assembly are all arranged on the rack; the monitoring assembly and the navigation assembly are both connected with the data acquisition cabin, and the guide mechanism is connected with the navigation assembly. According to the method, the monitoring path is established on the deep sea mud volcano, so that the monitoring mechanism periodically monitors the mud volcano along the monitoring path, and the topographic change and the activity rule of the mud volcano are obtained.

Description

technical field [0001] The invention relates to marine environment monitoring and detection equipment, in particular to an in-situ monitoring system and method for deep-sea mud volcanoes. Background technique [0002] Deep-sea mud volcanoes have always been a focus of attention in the development of deep-sea resources, and mud volcanoes have been in an unstable state for a long time, and their activities also have an uncertain periodicity. Global warming has a major impact. The current monitoring method for the periodic activities of deep-sea mud volcanoes, especially the terrain changes, is to use detection ships to enter the ocean for long-term monitoring. However, because the cost of using ships to conduct multiple multi-beam bathymetry The monitoring of deep-sea mud volcanoes is limited, and there is a lack of long-term time series testing of mud volcano topography, and the dynamic terrain changes and eruption activities of mud volcanoes cannot be obtained. Contents o...

Claims

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Application Information

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IPC IPC(8): G01D21/02G01S15/88G01K13/02G01N33/00G01C21/20
CPCG01D21/02G01S15/88G01K13/00G01N33/0047G01C21/203
Inventor 秦绪文吴婷婷尉建功
Owner GUANGZHOU MARINE GEOLOGICAL SURVEY
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