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Abstract

During the operation of oil and gas transportation pipeline, condensate forms on the inner wall of the pipeline can lead to reduced transportation efficiency and potential safety hazards. Pigging is a widely used technology to remove deposition in pipelines. From the studies, it is found that the effect of pigging largely depends on the structure of the pig. The jetting pig is a new type of pigging device designed to prevent the blocking in the pigging process, and its baffles play an important role in guiding the jet fluid. In this paper, the impact of the structure of the baffle plate on the downstream flow field of the jetting pig is simulated and analyzed. The surface of the baffle plate is changed by using the curve of the contraction section of the water tunnel. It is found that the baffle plate structure has a great influence on the flow field at the outlet of the jet pig: (1) The increase of buffle area leads to the increase of turbulent kinetic energy and the decrease of velocity; (2) The rise of edge angle lead to the regular change of turbulent kinetic energy; (3) Different curved surfaces make the change of turbulent kinetic energy and velocity. The results in this study are helpful for a better understanding of mechanism of jetting pig and improved design of mechanical structure for improved pigging performance.

Keywords

Jetting pig baffle plate crude and gas pipeline structural parameters CFD

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References

Venkatesan

Creek

. Wax deposition during production operations: SOTA. In: Proceedings of the offshore technology conference, Texas, U.S., 2007.

Venkatesan

Nagarajan

Paso

, et al. The strength of paraffin gels formed under static and flow conditions. Chem Eng Sci 2005; 60(13): 3587–3598.

Smith

Ramsden

RMJ

. The prediction of oil gelation in submarine pipelines and the pressure required for restarting flow. In: European offshore petroleum conference and exhibition, London, U.K., 1978.

Aiyejina

Chakrabarti

Pilgrim

, et al. Wax formation in oil pipelines: a critical review. Int J Multiphase Flow 2011; 37: 671–694.

Wang

Huang

. Prediction for wax deposition in oil pipelines validated by field pigging. J Energy Inst 2014; 87: 196–207.

Taitel

Dukler

. A model for predicting flow regime transitions in horizontal and near horizontal gas-liquid flow. AIChE J 1976; 22: 47–55.

Taitel

Lee

Dukler

. Transient gas-liquid flow in horizontal pipes: modeling the flow pattern transitions. AIChE J 1978; 24: 920–934.

Taitel

Shoham

Brill

. Simplified transient solution and simulation of two-phase flow in pipelines. Chem Eng Sci 1989; 44: 1353–1359.

Tan

Wang

Liu

, et al. Probing tribological properties of waxy oil in pipeline pigging with fluorescence technique. Tribol Int 2014; 71: 26–37.

10.

Zheng

Zhang

Huang

, et al. Effects of operating conditions on wax deposit carbon number distribution: theory and experiment. Energy Fuels 2013; 27: 7379–7388.

11.

Zhang

. Summary of modern pigging technology (in Chinese). Foreign Oilfield Eng 1998; 10: 33–36.

12.

Zhang

Dong

Cui

, et al. Stress and strain analysis of spherical sealing cups of fluid-driven pipeline robot in dented oil and gas pipeline. Eng Fail Anal 2020; 108: 104294.

13.

Shao

Yang

. A pigging technology for in-line inspection of products pipeline. Oil Gas Storage Transp 2019; 38: 1232–1239.

14.

Wang

Sarica

Chen

. An experimental study on mechanics of wax removal in pipeline. Energy Resour Technol 2005; 127: 302–309.

15.

Wang

Sarica

Volk

. An experimental study on wax removal in pipes with oil flow. Energy Resour Technol 2008; 130: 043001.

16.

Tan

Liu

Wang

, et al. Spatio-temporal structure in wax–oil gel scraping at a soft tribological contact. Tribol Int 2015; 88: 236–251.

17.

Tan

Liu

Wang

, et al. Tribological behaviours of wax-in-oil gel deposition in orthogonal cleaning process. Tribol Lett 2015; 57: 1–18.

18.

Lan

Liu

Xiao

, et al. Frictional behavior of wax–oil gels against steel. Tribol Lett 2017; 65: 88.

19.

Hendrix

Graafland

van Ostayen

. Frictional forces for disc-type pigging of pipelines. J Pet Sci Eng 2018; 171: 905–918.

20.

Alnaimat

Ziauddin

. Wax deposition and prediction in petroleum pipelines. J Pet Sci Eng 2020; 184: 250–257.

21.

Zhang

Liu

, et al. Measurement and analysis of friction and dynamic characteristics of PIG’s sealing disc passing through girth weld in oil and gas pipeline. Measurement 2015; 64: 112–122.

22.

McDonald

Baker

. A method of calculating multiphase flow in pipe lines using rubber spheres to control liquid holdup. Drill Prod Pract 1964; 56–68.

23.

Azevedo

Bracm

Nieckele

, et al. Simple hydrodynamicmodels for the prediction of pig motions in pipelines. In: Offshore technology conference, 1996, pp.729–739.

24.

Abood

Abdulwahid

Almudhaffar

. Comparison between the experimental and numerical study of (air-oil) flow patterns in vertical pipe. Case Stud Therm Eng 2019; 14: 100424.

25.

Mazreah

Alnaimi

FBI

Sahari

. Novel design for PIG to eliminate the effect of hydraulic transients in oil and gas pipelines. J Pet Sci Eng 2017; 156: 250–257.

26.

Morel

. Comprehensive design of axisymmetric wind tunnel contractions. J Fluid Eng 1975; 97: 225–233.

27.

Mikhail

. Optimum design of wind tunnel contractions. AIAA J 1979; 17: 471–477.

28.

. Flow analysis and design of three-dimensional wind tunnel contractions. AIAA J 1991; 29: 1912–1920.

29.

Fang

Chen

Hong

. Experimental and analytical evaluation of flow in a square-to-square wind tunnel contraction. J Wind Eng Ind Aerodyn 2001; 89: 247–262.

30.

Zhou

Wang

Chen

. Optimized design of the contraction in a minitype high-speed water-tunnel. J Ship Mech 2009; 13: 513–521.

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Impacts of structural parameters of baffle plate on jetting pigging robot in the underwater oil and gas pipeline

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