Authors: M. L. Arias, J. D’Adamo, M. N. Novosad, P. A. Raffo, H. P. Burbridge, G. O. Artana

Abstract:

Shale oils are highly paraffinic and, consequently, can create wax deposits that foul pipelines during transportation. Several factors must be considered when designing pipelines or treatment programs that prevent wax deposition: including chemical species in crude oils, flowrates, pipes diameters and temperature. This paper describes the wax deposition study carried out within the framework of YPF Tecnolgía S.A. (Y-TEC) flow assurance projects, as part of the process to achieve a better understanding on wax deposition issues. Laboratory experiments were performed on a medium size, 1 inch diameter, wax deposition loop of 15 meters long equipped with a solid detector system, online microscope to visualize crystals, temperature, and pressure sensors along the loop pipe. A baseline test was performed with diesel with no added paraffin or additive content. Tests were undertaken with different temperatures of circulating and cooling fluid at different flow conditions. Then, a solution formed with a paraffin incorporated to the diesel was considered. Tests varying flowrate and cooling rate were again run. Viscosity, density, WAT (Wax Appearance Temperature) with DSC (Differential Scanning Calorimetry), pour point and cold finger measurements were carried out to determine physical properties of the working fluids. The results obtained in the loop were analyzed through momentum balance and heat transfer models. To determine possible paraffin deposition scenarios temperature and pressure loop output signals were studied. They were compared with WAT static laboratory methods.

Keywords: Paraffin deposition, wax, oil pipelines, experimental pipe loop.

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References:

[1] P. Singh, R. Venkatesan, and H. Scott Fogler, “Formation and aging of incipient thin film wax-oil gels”. Materials, interfaces, and electrochemical phenomena, AIChE Journal, Vol. 46, No. 5, May 2000.
[2] B. Wright, B. and C. Sandu, “Processing shale oils requires innovative solutions”. HP Special report, July 2013.
[3] J.G. Gluyas, and J.R. Underhill, “The Staffa Field, Block 3/8b, UK North Sea”. Geological Society Publications, 20: 327-333, 2003
[4] M. Ichard, and M. Raviculé, “Técnicas de fluidodinámica computacional aplicadas al studio de la deposición de parafinas en tuberías”. XXI Congreso sobre Métodos Numéricos y sus Aplicaciones. ENIEF 2014. Bariloche, Argentina.
[5] H. P. Burbridge, F. Bacchi, A. E. Scarabino, and M. Raviculé, “Estudio computacional de la deposición de parafinas en tuberías con flujos turbulentos”. XXIII Congreso sobre Métodos Numéricos y sus Aplicaciones. ENIEF 2017. La Plata, Argentina.
[6] By Zhenyu Huang, Sheng Zheng, H. Scott Fogler. “Wax Deposition Experimental Characterizations, Theoretical Modeling, and Field Practices”. Taylor and Francis Group, ISBN 9780367783495, 184 Pages, Published March 31, 2021, by CRC Press.
[7] A. Aiyejina, D. P. Chakrabarti, A. Pilgrim, and M.K.S. Sastry, “Wax formation in oil pipelines: a critical review”. International journal of multiphase flow, Vol. 37, pp 671-694, 2011.
[8] R. Hoffmann, and L. Amundsen, “Single-phase wax deposition experiments”, Energy & Fuels, 24, 1069-1080, 2010.
[9] R. Tiwary, and A. K. Mehrotra, “Deposition from wax-solvent mixtures under turbulent flow: effects of shear rate and time on deposit properties”. Energy & Fuels, Vol. 23, No. 3, pp. 1299-1310, 2009.
[10] P. Singh, R. Venkatesan, and H. Scott Fogler, “Morphological evolution of thick wax deposits during aging”. Fluid Mechanics and transport phenomena, AIChE Journal, Vol. 47, No. 1, January 2001.
[11] P. Singh, R. Venkatesan, and H. Scott Fogler, “Existence of a critical carbon number in the aging of a wax-oil gel”. Thermodynamics, AIChE Journal, Vol. 47, No. 9, September 2001.
[12] C. Sarica, and E. Panacharoensawad, “Review of paraffin deposition research under multiphase flow conditions”. Energy & Fuels, Vol. 26, pp. 3968-3978, 2012.
[13] Kerstin Avila, David Moxey, Alberto De Lozar, Marc Avila, Dwight Barkley, and Björn Hof. The onset of turbulence in pipe flow. Science, 333 (6039):192–196, 2011.