Saturday, August 19, 2023

 

Monitoring wind, gas density and temperatures together can better predict mine disasters

Monitoring wind, gas density and temperatures together can better predict mine disasters
Shown is a UML model of a gas warning system comprised of three layers from
 the bottom to the top—data access layer, domain layer, and view layer: (1)
 Data acquisition: This logic flow is run between the Data Access Layer and
 Domain Layer. The data are obtained from gas, temperature, and wind 
databases. (2) Correlation analysis: Within the Domain Layer, correlation 
analyses are conducted separately between data upstream of gas and gas, gas 
and temperature, and gas and wind. (3) Activated decision: This step bridges 
the Domain Layer and the View Layer. 
Credit: Scientific Reports (2023). DOI: 10.1038/s41598-023-35900-3

Greater monitoring of wind, gas density and temperatures in coal mines can help reduce the risk of disasters, according to a new joint study with Charles Darwin University (CDU) and University Technology Sydney (UTS).

The study, "An FSV analysis approach to verify the robustness of the triple-correlation analysis ," focused on developing a gas monitoring system that takes a holistic approach to assessing wind, gas, and temperature conditions. It was published in Scientific Reports.

The project used data from a large Global Fortune 500 listed  in China, which held 46% of the world's coal production in 2020.

Co-author and CDU Faculty of Science and Technology Associate Professor Niusha Shafiabady said the study examined  and all tests indicated three significant correlations between gas, temperature, and wind.

The project confirmed the framework could be used to develop a gas warning system with improved sensitivity to reduce the incidence of gas explosions.

"A significant number (3,284) of  have high gas content at outburst-prone risk levels across almost all 26 major coal mining provinces in China," Shafiabady said.

"For example on 10 June 2020, a serious coal and gas outburst accident occurred in Liaoyuan, China which resulted in seven deaths and two injuries, with a direct economic loss of 16.66 million yuan ($3.4 million).

"It is significant to carry out real-time monitoring of coal and rock dynamic disasters during coal mining activities."

The study was undertaken by CDU, University of Technology Sydney, Shanxi Normal University, Central Queensland University, Taiyuan Normal University, Shanxi Fenxi Mining Industry Group Co and Shanxi Fenxi Mining Zhongxing Coal Industry Co.

Shafiabady said the results of the study could be used by different mining companies to avoid gas incidents.

"The outcomes of this study can also be used in other industries such as chemical industry, oil and gas industry,  and semiconductor manufacturing industries," she said.

"Currently we are working on creating a real-time artificial intelligence decision-making system with the ability to predict the accidents as an addition to the current designed gas monitoring system."

More information: Robert M. X. Wu et al, An FSV analysis approach to verify the robustness of the triple-correlation analysis theoretical framework, Scientific Reports (2023). DOI: 10.1038/s41598-023-35900-3

Journal information: Scientific Reports 

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