Gas Leak Real-time Detection and Volume Flow Quantification Based on Infrared Imaging and Advanced Algorithms

Due to the semi-transparent and irregular nature of gases, it is still a highly challenging task to effectively detect and quantify gas leaks especially those with small flow rates by only utilizing economical equipments. In this paper, we present a strategy for automating real-time identification a...

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Bibliographic Details
Published in:IEEE access 2025-01, Vol.13, p.1-1
Main Authors: Yan, Man, Li, Zhou, Dong, Zheng, Liu, Yiming, Chen, Liyun, Wu, Xiaosong, Wu, Lijun
Format: Article
Language:English
Subjects:
Accuracy
Cameras
Clustering algorithms
DeeplabV3+ neural network
Fluid flow
Gas identification
Gas lasers
Gas quantification
Gases
Image edge detection
Kmeans clustering algorithm
Optical filters
Optical flow method
Real-time systems
Training
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Summary:Due to the semi-transparent and irregular nature of gases, it is still a highly challenging task to effectively detect and quantify gas leaks especially those with small flow rates by only utilizing economical equipments. In this paper, we present a strategy for automating real-time identification and quantification of gases in the mid-infrared band by combining an infrared camera combined with a series optimized algorithms. A basic network DeepLabV3+ is first modified by replacing its Xception backbone with MobileNetv2 for real-time gas detection and segmentation. Then special attention mechanisms tailored to the characteristics of the gas are added into the network to enhance the perception and recognition of the gas edges. The optimized Kmeans clustering algorithm is integrated to identify the Region of Interest (ROI) in the image containing the target gas. The quantification of the volume flow rate within the ROI is realized by integrating the radiation transfer model with the optical flow method. The experimental results indicate that the quantification limit of the gas flow rate can reach 0.01 L/min, which is comparable to that obtained by the methods with complicated instruments. Our detection and quantification strategy can find vast applications in hazardous gas monitoring field.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2025.3525764