Structural optimization strategy of pipe isolation tool by dynamic plugging process analysis 被引量：3

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摘要 During the pipeline plugging process,both the pipeline and the pipe isolation tool(PIT)will be greatly damaged,due to the violent vibration of the flow field.In this study,it was proposed for the first time to reduce the vibration of the flow field during the plugging process by optimizing the surface structure of the PIT.Firstly,the central composite design(CCD)was used to obtain the optimization schemes,and the drag coefficient and pressure coefficient were proposed to evaluate the degree of flow field changes.Secondly,a series of computational fluid dynamics(CFD)simulations were performed to obtain the drag coefficient and pressure coefficient during dynamic plugging.And the mathematical model of drag coefficient and pressure coefficient with the surface structure of the PIT were established respectively.Then,a modified particle swarm optimization(PSO)was applied to predict the optimal value of the surface structure of the PIT.Finally,an experimental rig was built to verify the effectiveness of the optimization.The results showed that the improved method could reduce the flow field vibration by 49.56%.This study provides a reference for the design of the PIT surface structure for flow field vibration technology.

作者 Ting-Ting Wu Hong Zhao Bo-Xuan Gao Fan-Bo Meng

机构地区 College of Mechanical and Transportation Engineering

出处《Petroleum Science》 SCIE CAS CSCD 2021年第6期1829-1839,共11页 石油科学（英文版）

基金 financially supported by the National Natural Science Foundation of China(Grant No.51575528)。

关键词 Pipe isolation tool Dynamic analysis Drag coefficient Pressure coefficient Modified particle swarm optimization algorithm

分类号 TE973.8 [石油与天然气工程—石油机械设备]

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