TY - GEN
T1 - Prediction of Gas-Liquid Flow Parameters in Pipes Based on Physics-Informed Neural Network
AU - Ding, Nanxi
AU - Lou, Wenzhong
AU - Xuan, Weikun
AU - Zhao, Fei
AU - Zhang, Zihao
N1 - Publisher Copyright:
© Beijing HIWING Scientific and Technological Information Institute 2024.
PY - 2024
Y1 - 2024
N2 - Gas-liquid two-phase flow is a prevalent phenomenon in unmanned industrial settings, and understanding the vortex behavior in pipes is crucial for its analysis and prediction. The occurrence of vortex is intricately linked to fluid velocity, pressure distribution, and pipe geometry. Accordingly, the presence of vortex induces friction and vibration on the pipe wall, thereby impacting the mechanical properties of the pipe. Presently, many investigations on gas-liquid two-phase flow vortex in pipes rely on conventional computational fluid dynamics (CFD) methods, which suffer from lengthy computational cycles. Conversely, some studies employ deep learning techniques for flow field prediction, albeit requiring extensive data. To address these challenges, this paper simplifies the model to a homogeneous flow, exploits the physical information neural network for spatial and temporal prediction of parameters distribution in gas-liquid two-phase flow within pipes, as well as proposes the utilization of the weak-constrain 4DVar approach to refine the data. This framework resolves the computational inefficiency and data-intensive nature of CFD and NN method. Moreover, the impact of different neural network structures on prediction accuracy is investigated. By comparing with the validation data, it is observed that the method proposed in this study achieves an accuracy with an error less than 2%, which has a SOTA performance, and the prediction time is shortened to less than twenty minutes compared with the dozens of hours required by traditional CFD.
AB - Gas-liquid two-phase flow is a prevalent phenomenon in unmanned industrial settings, and understanding the vortex behavior in pipes is crucial for its analysis and prediction. The occurrence of vortex is intricately linked to fluid velocity, pressure distribution, and pipe geometry. Accordingly, the presence of vortex induces friction and vibration on the pipe wall, thereby impacting the mechanical properties of the pipe. Presently, many investigations on gas-liquid two-phase flow vortex in pipes rely on conventional computational fluid dynamics (CFD) methods, which suffer from lengthy computational cycles. Conversely, some studies employ deep learning techniques for flow field prediction, albeit requiring extensive data. To address these challenges, this paper simplifies the model to a homogeneous flow, exploits the physical information neural network for spatial and temporal prediction of parameters distribution in gas-liquid two-phase flow within pipes, as well as proposes the utilization of the weak-constrain 4DVar approach to refine the data. This framework resolves the computational inefficiency and data-intensive nature of CFD and NN method. Moreover, the impact of different neural network structures on prediction accuracy is investigated. By comparing with the validation data, it is observed that the method proposed in this study achieves an accuracy with an error less than 2%, which has a SOTA performance, and the prediction time is shortened to less than twenty minutes compared with the dozens of hours required by traditional CFD.
KW - Gas-liquid flow
KW - PINN
KW - Velocity prediction
KW - Vortex
KW - Weak-constrain 4DVar
UR - http://www.scopus.com/inward/record.url?scp=85192389937&partnerID=8YFLogxK
U2 - 10.1007/978-981-97-1087-4_13
DO - 10.1007/978-981-97-1087-4_13
M3 - Conference contribution
AN - SCOPUS:85192389937
SN - 9789819710867
T3 - Lecture Notes in Electrical Engineering
SP - 132
EP - 144
BT - Proceedings of 3rd 2023 International Conference on Autonomous Unmanned Systems (3rd ICAUS 2023) - Volume III
A2 - Qu, Yi
A2 - Gu, Mancang
A2 - Niu, Yifeng
A2 - Fu, Wenxing
PB - Springer Science and Business Media Deutschland GmbH
T2 - 3rd International Conference on Autonomous Unmanned Systems, ICAUS 2023
Y2 - 9 September 2023 through 11 September 2023
ER -