基于递归特性和CNN的上升管内气液两相流型识别研究

doi:10.11949/0438-1157.20251261

摘要/Abstract

摘要：

针对集输-上升管路系统内气液两相流流型识别困难的问题，提出一种融合压差数据递归图和卷积神经网络的流型识别方法。在集输-上升管路系统利用空气和水为介质开展了两相流实验，观察到泡状流、环状流、弹状流和严重段塞流4类典型流型。基于相空间重构方法构建了各流型压差信号的递归图，发现4种流型的递归图均呈现不同的特征。构建了3种不同的经典卷积神经网络（ LeNet、AlexNet、ResNet），用于提取流型压差数据递归图的对角线结构与网格状结构特征，并采用ROC（受试者工作特征曲线，Receiver Operating Characteristic Curve）的AUC（曲线下的面积，Area Under Curve）对模型性能进行评价。结果表明：LeNet对各流型的识别取得了最高的精确率、灵敏度和特异度。

关键词: 上升管, 气液两相流, 流型识别, 卷积神经网络, 实验验证

Abstract:

A flow pattern recognition method that combines pressure difference data recursive graph and convolutional neural network is proposed to address the difficulty of identifying gas-liquid two-phase flow patterns in the gathering and lifting pipeline system. Two-phase flow experiments were conducted using air and water as media in the gathering and lifting pipeline system, and four typical flow patterns were observed: bubbly flow, annular flow, slug flow, and severe slug flow. Based on the phase space reconstruction method, recursive graphs of pressure difference signals for each flow pattern were constructed, and it was found that the recursive graphs of the four flow patterns all exhibited different characteristics. Due to the relatively regular period of annular flow, there are more main diagonals in the recursive plot, and the state trajectory has higher repeatability, showing a more regular appearance; For bubbly flow, due to the random distribution of bubbles, the pressure difference signal exhibits irregularity in the recursive graph, with isolated points occupying a large proportion and fewer diagonal structures, presenting a certain degree of randomness; For slug flow, in the state of intermittent motion between gas and liquid phases, short diagonal lines and block like small structures coexist in the recursive graph. Three different classical convolutional neural networks (LeNet, AlexNet, ResNet) were constructed to extract the diagonal and grid like features of the recursive graph of flow regime pressure difference data. The model performance was evaluated using the AUC (Area Under Curve) of Receiver Operating Characteristic Curve (ROC). The results showed that LeNet achieved the highest accuracy, sensitivity, and specificity in identifying various flow patterns.

Key words: riser, gas-liquid flow, flow pattern identification, convolutional neural network, experimental validation

中图分类号:

TK124

王佳豪, 黄玥程, 张一帆, 张家略, 韦德生, 苏若熙, 黄坤, 李乃良. 基于递归特性和CNN的上升管内气液两相流型识别研究[J]. 化工学报, DOI: 10.11949/0438-1157.20251261.

Jiahao WANG, Yuecheng HUANG, Yifan ZHANG, Jialue ZHANG, Desheng WEI, Ruoxi SU, Kun HUANG, Nailiang LI. Identification of gas-liquid two-phase flow patterns in a riser based on recursive characteristics and CNN[J]. CIESC Journal, DOI: 10.11949/0438-1157.20251261.

图/表 11

图1 实验系统示意图

Fig. 1 Schematic diagram of experimental system

图2 实验中观察到的四种典型流型

Fig.2 Four typical flow patterns observed in the experiment

图3 四种典型流型的递归图

Fig.3 Recurrence plots of the four typical flow patterns

图4 基于LeNet网络的流型识别模型

Fig.4 Flow pattern recognition model based on LeNet network

表1 三种模型的结构尺寸

Table 1 Structure and size of the three models

模型类型	输入层尺寸	卷积核尺寸	池化核尺寸	全连接层正则化参数	输出层维度
LeNet	32,32,1	5×5	2×2	0.3	4
AlexNet	224,224,1	3×3	2×2	0.6	4
ResNet	224,224,3	7×7	7×7	0.6	4

表2 三种模型的超参数

Table 2 Hyperparameters of the three models

神经网络	迭代次数	批次大小	学习率
LeNet	200	10	0.00010
AlexNet	200	8	0.00010
ResNet	200	8	0.00002

图5 LeNet模型在训练集与验证集上的损失率和准确率曲线

Fig.5 Loss and accuracy curves of LeNet model on training and validation data set

图6 LeNet模型的混淆矩阵

Fig.6 Confusion matrix of LeNet model

表3 LeNet模型的流型识别效果

Table 3 Flow pattern recognition performance of LeNet model

流型	样本数量	精确率	Recall	特异度	灵敏度	F1
环状流	1400	0.86	0.86	0.98	0.96	0.90
泡状流	1400	0.96	0.96	0.95	0.87	0.91
弹状流	1400	1.00	1.00	1.00	1.00	1.00
段塞流	1400	1.00	1.00	1.00	1.00	1.00
总数	5600

表4 三种模型的识别性能对比

Table 4 Comparison of recognition performance of the three models

模型	精确率	特异性	灵敏度	F1
LeNet	0.967	0.967	0.969	0.977
AlexNet	0.966	0.966	0.967	0.966
ResNet	0.873	0.873	0.909	0.866

图7 三种模型的ROC曲线

Fig.7 ROC curves of the three models

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