Measurement and analysis of friction and dynamic characteristics of PIG’s sealing disc passing through girth weld in oil and gas pipeline

Abstract Pipeline inspection gauges (PIGs) are needed for operations such as dewatering, cleaning and internal inspection of the oil and gas pipelines to facilitate improvement in efficiency and safety. The friction and dynamic characteristics, as the sealing disc of a PIG passes through the girth weld in a pipe, has been directly studied using a custom-built experimental setup. The contact behavior between sealing disc and girth weld was analyzed using finite element methods. A two-dimensional section analytical link model of the sealing disc is introduced here and was simulated using the mechanic dynamic analysis software Adams. Our results show that the process of the sealing disc of the PIG passing through the girth weld in the pipe can be separated into three distinct stages: (1) start-up stage, (2) climbing stage, and (3) slope stage. At first, the PIG decelerates due to the friction force and then accelerates after passing through the girth weld. The acceleration and deceleration processes produce axial vibration in PIG.

[1]  V. E. Loskutov,et al.  Improving the quality of diagnostics of gas-main pipelines by using a device for automated control of the velocity of pig flaw detectors , 2008 .

[2]  V. E. Loskutov,et al.  Automated control of the velocity of in-tube diagnostic tools for main gas pipelines: I. Development, design, and operating principle of a bypass device , 2007 .

[3]  Angela O. Nieckele,et al.  Transient Pig Motion Through Gas and Liquid Pipelines , 2001 .

[4]  Wolf B. Dapp,et al.  Self-affine elastic contacts: percolation and leakage. , 2012, Physical review letters.

[5]  B. Persson Theory of rubber friction and contact mechanics , 2001 .

[6]  V. E. Loskutov,et al.  Automated control of the velocity of in-tube diagnostic tools for main gas pipelines: II. Electronic equipment of a bypass device , 2007 .

[7]  Germany,et al.  Rubber friction on wet and dry road surfaces: The sealing effect , 2005 .

[8]  V. I. Shcherbakov,et al.  Selection of structural parameters of an inspection pig for arterial oil and gas pipelines from conditions of dynamics , 2013, Chemical and Petroleum Engineering.

[9]  Deguo Wang,et al.  Linear polymer aqueous solutions in soft lubrication: From boundary to mixed lubrication , 2013 .

[10]  Wenming Wang,et al.  Experimental study on dynamics of rotatable bypass-valve in speed control pig in gas pipeline , 2014 .

[11]  A. M. Podgorbunskikh Devices for automated regulation of the velocity of in-tube pig flaw detectors (Review) , 2008 .

[12]  Liu Shuhai,et al.  Frictional behaviors of rough soft contact on wet and dry pipeline surfaces: With application to deepwater pipelaying , 2013 .

[13]  Alireza Arab Solghar,et al.  Analysis of transient PIG motion in natural gas pipeline , 2012 .

[14]  A. O. Nieckele,et al.  DESIGN AND CONTROL OF PIG OPERATIONS THROUGH PIPELINES , 2008 .

[15]  M. Erdogmus,et al.  To Pig or Not to Pig: The Marlin Experience With Stuck Pig , 2006 .

[16]  Fabrice Deleau,et al.  Sliding friction at elastomer/glass contact: Influence of the wetting conditions and instability analysis ☆ , 2009 .

[17]  Ali Nabi,et al.  Investigation of Dynamics and Vibration of PIG in Oil and Gas Pipelines , 2007 .

[18]  Deguo Wang,et al.  In Situ Observation of Wax-in-Oil Flow in Rough Soft Contact , 2013, Tribology Letters.

[19]  V. I. Shcherbakov,et al.  Self-oscillation of flaw-detection equipment for arterial gas pipelines , 2012, Chemical and Petroleum Engineering.

[20]  Dariush Mowla,et al.  Mathematical modeling and simulation of pigging operation in gas and liquid pipelines , 2009 .