nach oben

Journal of Engineering Mathematics

Erschienen in:

01.12.2017

Primary cementing of oil and gas wells in turbulent and mixed regimes

verfasst von: Amir Maleki, Ian Frigaard

Erschienen in: Journal of Engineering Mathematics | Ausgabe 1/2017

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

We present a detailed derivation of a practical two-dimensional model for turbulent and mixed regimes in narrow annular displacement flows, such as are found during the primary cementing of oil and gas wells. Such mixed cross regimes, including those in which different regimes exist in the same annular cross section, are relatively common in primary cementing. The modelling approach considers scaling based on the disparity of length-scales, which allows a narrow-gap averaging approach to be effective. With respect to the momentum equations, the leading-order equations correspond to a turbulent shear flow in the direction of the modified pressure gradient. This leads to a nonlinear elliptic problem that is the natural extension of the laminar displacement model in Bittleston et al. (J Eng Math 43:229–253, 2002). The mass transport equations that model the miscible displacement are however quite different. To leading-order turbulence effectively mixes the fluids. Changes in concentrations within the annular gap arise due to the combined effects of advection with the mean flow, anisotropic Taylor dispersion (along the streamlines) and turbulent diffusivity. The diffusive and dispersive effects are modelled for fully turbulent and transitional flows following Maleki and Frigaard (J Non-Newt Fluid Mech 235:1–19, 2016). The model derived allows the investigation of different well geometries and inclinations, pumping sequences and fluid rheologies, all of which can have importance. A number of computed examples are presented with the aim of demonstrating the complexity of turbulent displacements.

Vorheriger Artikel Simulations of a heavy ball falling through a sheared suspension

Nächster Artikel Ferrofluids and magnetically guided superparamagnetic particles in flows: a review of simulations and modeling

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Nur mit Berechtigung zugänglich

A liner is a casing that extends downwards from just above the previous casing.

Guillot D, Nelson E (2006) Well Cementing. Schlumberger Educational Services, Sugar Land

Brice JW Jr, Holmes BC (1964) Engineered casing cementing programs using turbulent flow techniques. J Petrol Technol 16:503–508CrossRef

Couturler M, Guillot D, Hendriks H, Callet F (1990) Design rules and associated spacer properties for optimal mud removal in eccentric annuli. In: CIM/SPE international technical meeting. Society of Petroleum Engineers paper 21594

Jamot A (1974) Déplacement de la boue par le latier de ciment dans l espace annulaire tubage-paroi d un puits. Revue Assoc. Franc. Techn. Petr 224:27–37

Lockyear CF, Ryan DF, Gunningham MM (1990) Cement channeling: how to predict and prevent. Society of Petroleum Engineers, SPE paper 19865

Bittleston SH, Ferguson J, Frigaard IA (2002) Mud removal and cement placement during primary cementing of an oil well- Laminar non-Newtonian displacements in an eccentric annular Hele-Shaw cell. J Eng Math 43:229–253CrossRefMATHMathSciNet

Pelipenko S, Frigaard IA (2004) Two-dimensional computational simulation of eccentric annular cementing displacements. IMA J App Math 69:557–583

Carrasco-Teja M, Frigaard IA, Seymour BR, Storey S (2008) Viscoplastic fluid displacements in horizontal narrow eccentric annuli: stratification and travelling wave solutions. J Fluid Mech 605:293ADSCrossRefMATHMathSciNet

Pelipenko S, Frigaard IA (2004) On steady state displacements in primary cementing of an oil well. J Eng Math 46:1–26CrossRefMATH

10.

Pelipenko S, Frigaard IA (2004) Visco-plastic fluid displacements in near-vertical narrow eccentric annuli: prediction of travelling-wave solutions and interfacial instability. J Fluid Mech 520:343–377ADSCrossRefMATHMathSciNet

11.

Bogaerts M, Azwar M, Dooply M, Salehpoor A (2015) Well cementing: an integral part of well integrity. In: Offshore Technology Conference Brasil, Rio de Janeiro, Brazil, 27th–29th October 2015. OTC-26314-MS

12.

Gregatti A, Carvalho G, Piedade T, Campos G (2015) Cementing in front of saline zone and carbonate reservoir with presence of \(\text{CO}_\text{2 }\). In: OTC Brasil

13.

Guo Y, Qi J, Zheng YS, Taoutaou S, Wang R, An Y, Guo H (2015) Cementing optimization through an enhanced ultrasonic imaging tool. SPE paper 176069-MS

14.

Osayande V, Isgenderov I, Bogaerts M, Kurawle I, Florez P (2004) Beating the odds with channeling in erd well cementing: solution to persistent channeling problems. Society of Petroleum Engineers, SPE paper 171271-MS

15.

Watson TL (2004) Surface casing vent flow repair-a process. In: Canadian International petroleum conference, Calgary, Alberta, 8th-10th June 2004. PETSOC-2004-297

16.

McLean RH, Manry CW, Whitaker WW (1967) Displacement mechanics in primary cementing. Society of Petroleum Engineers, SPE paper 1488

17.

Allouche M, Frigaard IA, Sona G (2000) Static wall layers in the displacement of two visco-plastic fluids in a plane channel. J. Fluid Mech. 424:243–277ADSCrossRefMATH

18.

Frigaard IA, Leimgruber S, Scherzer O (2003) Variational methods and maximal residual wall layers. J Fluid Mech 483:37–65ADSCrossRefMATHMathSciNet

19.

Wielage-Burchard K, Frigaard IA (2011) Static wall layers in plane channel displacement flows. J Non-Newt Fluid Mech 166:245–261CrossRefMATH

20.

Zare A, Roustaei A, Frigaard IA (2017) Buoyancy effects on micro-annulus formation: Newtonian-bingham fluid displacements in vertical channels. J Non-Newt Fluid Mech (submitted)

21.

Alba K, Taghavi SM, Frigaard IA (2013) Miscible density-unstable displacement flows in inclined tube. Phys Fluids 25:067101ADSCrossRef

22.

Taghavi SM, Alba K, Seon T, Wielage-Burchard K, Martinez DM, Frigaard IA (2012) Miscible displacement flows in near-horizontal ducts at low atwood number. J Fluid Mech 696:175–214ADSCrossRefMATHMathSciNet

23.

Moyers-Gonzalez MA, Frigaard IA (2008) Kinematic instabilities in two-layer eccentric annular flows, part 1: Newtonian fluids. J Eng Math 62:103–131CrossRefMATH

24.

Moyers-Gonzalez MA, Frigaard IA (2009) Kinematic instabilities in two-layer eccentric annular flows, part 2: shear-thinning and yield-stress effects. J Eng Math 65:25–52CrossRefMATH

25.

Dusseault MB, Jackson RE, Macdonald D (2014) Towards a road map for mitigating the rates and occurrences of long-term wellbore leakage. University of Waterloo and Geofirma Engineering LTD, Waterloo

26.

Watson TL, Bachu S (2008) Identification of wells with high CO\(_2\)-leakage potential in mature oil fields developed for \(\text{ CO }_\text{2 }\)-enhanced oil recovery. In: SPE symposium on improved oil Recovery. Society of Petroleum Engineers

27.

Watson TL, Bachu S (2009) Evaluation of the potential for gas and \(\text{ CO }_\text{2 }\) leakage along wellbores. SPE Drill. Complet. 24:115–126

28.

Carrasco-Teja M, Frigaard IA (2010) Non-Newtonian fluid displacements in horizontal narrow eccentric annuli: effects of slow motion of the inner cylinder. J Fluid Mech 653:137–173ADSCrossRefMATHMathSciNet

29.

Tardy PMJ, Bittleston SH (2015) A model for annular displacements of wellbore completion fluids involving casing movement. J Pet Sci Eng 126:105–123CrossRef

30.

Chung SY, Rhee GH, Sung HJ (2002) Direct numerical simulation of turbulent concentric annular pipe flow—Part 1: flow field. Int J Heat Fluid Flow 23:426–440CrossRef

31.

Freund JB, Lele SK, Moin P (2000) Compressibility effects in a turbulent annular mixing layer. Part 1. Turbulence and growth rate. J Fluid Mech 421:229–267ADSCrossRefMATHMathSciNet

32.

Nikitin N, Wang H, Chernyshenko S (2009) Turbulent flow and heat transfer in eccentric annulus. J Fluid Mech 638:95–116ADSCrossRefMATH

33.

Nouri JM, Whitelaw JH (1997) Flow of Newtonian and non-Newtonian fluids in an eccentric annulus with rotation of the inner cylinder. Int J Heat Fluid Flow 18(2):236–246CrossRef

34.

Sawko RAC (2012) Mathematical and computational methods of non-Newtonian, multiphase flows. Ph.D. Thesis, Cranfield University

35.

Maleki A, Frigaard IA (2016) Axial dispersion in weakly turbulent flows of yield stress fluids. J Non-Newt Fluid Mech 235:1–19CrossRefMathSciNet

36.

Dodge DW, Metzner AB (1959) Turbulent flow of non-Newtonian systems. AIChE J 5:189–204CrossRef

37.

Dodge DW, Metzner AB (1962) Errata. AIChE J 8:143

38.

Metzner AB, Reed JC (1955) Flow of non-Newtonian fluids: correlation of the laminar, transition, and turbulent-flow regions. AIChE J 1:434–440CrossRef

39.

Taghavi SM, Frigaard IA (2013) Estimation of mixing volumes in buoyant miscible displacement flows along near-horizontal pipes. Can J Chem Eng 91:399–412CrossRef

40.

Zhang J, Frigaard IA (2006) Dispersion effects in the miscible displacement of two fluids in a duct of large aspect ratio. J Fluid Mech 549:225–251ADSCrossRefMathSciNet

41.

Fowler AC (1998) Mathematical models in the applied sciences. Cambridge University Press, CambridgeMATH

42.

Taylor GI (1954) The dispersion of matter in turbulent flow through a pipe. Proc R Soc Lond A 223:446–468ADSCrossRef

43.

Barenblatt GI, Entov VM, Ryzhik VM (1989) Theory of fluid flows through natural rocks. Kluwer Academic, DordrechtMATH

44.

Spena FR, Vacca A (2001) A potential formulation of non-linear models of flow through anisotropic porous media. Transp Porous Med 45(3):405–421CrossRefMathSciNet

45.

Glowinski R (1984) Numerical methods for nonlinear variational problems. Springer, New YorkCrossRefMATH

Titel: Primary cementing of oil and gas wells in turbulent and mixed regimes
verfasst von: Amir Maleki
Ian Frigaard
Publikationsdatum: 01.12.2017
Verlag: Springer Netherlands
Erschienen in: Journal of Engineering Mathematics / Ausgabe 1/2017
Print ISSN: 0022-0833
Elektronische ISSN: 1573-2703
DOI: https://doi.org/10.1007/s10665-017-9914-x

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 1/2017

On Boussinesq’s problem for a cracked halfspace

Flooding and sinking of an originally skimming body

Compressibility effects on outflows in a two-fluid system. 1. Line source in cylindrical geometry

Compressibility effects on outflows in a two-fluid system. 2. Point source in spherical geometry

Motion of a spherical liquid drop in simple shear flow next to an infinite plane wall or fluid interface

Interacting convection modes in a saturated porous medium of nearly square planform: a special case

Premium Partner

Marktübersichten