Gas Flow in Cements

Cheung, P.R.; Beirute, R.M.

doi:10.2118/11207-pa

Cited by 61 publications

(18 citation statements)

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“…According to several authors, the most frequent failure in a wellbore is casing or well annulus failure [e.g., Cooke, 1979;Cheung and Beirute, 1985;Sepos and Cart, 1985;Schmitz et al, 1996;Brooks et al, 2008;Watson and Bachu, 2009;Gorody, 2012;Muehlenbachs, 2012;Dusseault and Jackson, 2014]. Any failure to seal gasproducing intervals (whether or not targeted as the producing zone) and/or inadequate cementation of the borehole casing annulus (i.e., discontinuities and microchannels in the cement column, between the cement and surrounding rock formations and between the casing and surrounding cement) can create a leakage pathway [Watson and Bachu, 2009] which can lead to upward migration of fluids (in this study including formation fluid and gas) by advective or diffusive processes [Dusseault et al, 2000].…”

Section: Water Resources Researchmentioning

confidence: 99%

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Nowamooz

Lemieux

Molson

et al. 2015

Water Resources Research

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Methane and brine leakage rates and associated time scales along the cemented casing of a hypothetical decommissioned shale gas well have been assessed with a multiphase flow and multicomponent numerical model. The conceptual model used for the simulations assumes that the target shale formation is 200 m thick, overlain by a 750 m thick caprock, which is in turn overlain by a 50 m thick surficial sand aquifer, the 1000 m geological sequence being intersected by a fully penetrating borehole. This succession of geological units is representative of the region targeted for shale gas exploration in the St. Lawrence Lowlands (Qu ebec, Canada). The simulations aimed at assessing the impact of well casing cementation quality on methane and brine leakage at the base of a surficial aquifer. The leakage of fluids can subsequently lead to the contamination of groundwater resources and/or, in the case of methane migration to ground surface, to an increase in greenhouse gas emissions. The minimum reported surface casing vent flow (measured at ground level) for shale gas wells in Quebec (0.01 m 3 /d) is used as a reference to evaluate the impact of well casing cementation quality on methane and brine migration. The simulations suggest that an adequately cemented borehole (with a casing annulus permeability k c 1 mD) can prevent methane and brine leakage over a time scale of up to 100 years. However, a poorly cemented borehole (k c ! 10 mD) could yield methane leakage rates at the base of an aquifer ranging from 0.04 m 3 /d to more than 100 m 3 /d, depending on the permeability of the target shale gas formation after abandonment and on the quantity of mobile gas in the formation. These values are compatible with surface casing vent flows reported for shale gas wells in the St. Lawrence Lowlands (Quebec, Canada). The simulated travel time of methane from the target shale formation to the surficial aquifer is between a few months and 30 years, depending on cementation quality and hydrodynamic properties of the casing annulus. Simulated longterm brine leakage rates after 100 years for poorly cemented boreholes are on the order of 10 25 m 3 /d (10 mL/d) to 10 23 m 3 /d (1 L/d). Based on scoping calculations with a well-mixed aquifer model, these rates are unlikely to have a major impact on groundwater quality in a confined aquifer since they would only increase the chloride concentration in a pristine aquifer to 1 mg/L, which is significantly below the commonly recommended aesthetic objective of 250 mg/L for chloride.

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Section: Water Resources Researchmentioning

confidence: 99%

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Nowamooz

Lemieux

Molson

et al. 2015

Water Resources Research

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“…Permeability of the cement slurry to gas during setting time was evaluated at up to 120°C by means of a gas-flow apparatus (Fig.6) described in the literature [2]. The design of the instrument simulates the geometry and the physical condition inside a vertical well when the cement slurry is placed down-hole and starts the setting process in the presence of a gas pressure acting laterally (Fig.…”

Section: Methodsmentioning

confidence: 99%

“…The problems associated with gas migration during the setting of a cement in a natural gas well has been studied extensively [1][2][3][4][5]. Gas migration arises when gas present in the foonation exerts pressure against the cement slurry column causing the foonation of micro-fractures in the cement matrix while the slurry is hardening.…”

Section: Introductionmentioning

confidence: 99%

Carbon Black: A Low Cost Colloidal Additive for Controlling Gas-Migration in Cement Slurries

Calloni¹,

Moroni²,

Miano³

1995

SPE International Symposium on Oilfield Chemistry

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The effect of different additives on the permeability of cement slurries to formation gas has been studied with the aid of a gas flow apparatus. The performance of two commercial additives (polymer latex and silica fume) has been compared to that of a novel additive (carbon black) that has been developed in our laboratories with the aim of simplifying the cement slurry composition and reducing field operational costs. Data on the thickening time, fluid loss, rheology and compressive strength are also presented to provide a clear picture of the potential of carbon black as a substitute for silica fume and polymer latex in some field applications. Finally, the paper describes the results of a field application using carbon black as a gas-block additive in the cement slurry. Introduction The problems associated with gas migration during the setting of a cement in a natural gas well has been studied extensively [1–5]. Gas migration arises when gas present in the formation exerts pressure against the cement slurry. Considerable research has been devoted to identify the causes which favour gas migration and to develop additives capable of sealing the cement column at the interface with the gas-rich formation and with the casing [6–7]. The principal causes of gas migration arise from:Insufficient removal of drilling fluids.Weak sealing between the cement and the casing or between cement and the formation.Excess fluid loss and shrinkage of the setting cement.Bad design of the slurry's composition so that there is an inadequate cement column exerting hydrostatic pressure at the interface with the formation.

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“…In addition, fluid loss additives minimize the ability of fluids to flow though the cement porosity. Using expansion additives improve bonding at the casing/cement and cement/formation (Cheung and Beirute, 1985).…”

Section: Introductionmentioning

confidence: 99%

An Innovative Cement Formula To Prevent Gas Migration Problems in HT/HP Wells

Al-Yami

Nasr‐El‐Din

Al-Humaidi

2009

SPE International Symposium on Oilfield Chemistry

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Gas Migration through cement columns has been an industry problem for many years. The most problematic areas for gas migrations occur in deep gas wells. To control gas migration, cement densities required to successfully cement the zone could be as high as 170 pcf (Pounds per Cubic Foot). As cement slurry sets, hydrostatic pressure is reduced on the formation. During this transition, reservoir gases can travel up through the cement column resulting in gas being present at the surface. The permeable channels, from which gas flows, cause operational and safety problems at the well site.Current high density cement formulations do not provide good gas migration prevention due to settling and subsequent increase in permeability. To address the settling problem and reduce permeability of cement, a formula that resulted in great gas prevention was developed.A gas migration set-up helped in testing and optimizing cement formulations to measure gas flow through cement columns. The gas migration set up consisted of the following components: computer, data acquisition, full-length permeability determination, two partial length permeability determinations, cement volume change measurement, gas flow meter, and electronic filtrate weight determination. The pressure and temperature limitations are 2,000 psi maximum and 350°F. Different chemicals for gas migration prevention were evaluated. Special types of cements were designed and evaluated for possible use for cementing gas wells. Addition of inert particles to cement and their effect on gas migration prevention was investigated.In this paper, a new cement system was developed and resulted in significant gas prevention. The performance of this system outperforms available formulations and has great potential to improve wellbore isolation in deep gas wells.

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Gas Flow in Cements

Cited by 61 publications

References 0 publications

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Carbon Black: A Low Cost Colloidal Additive for Controlling Gas-Migration in Cement Slurries

An Innovative Cement Formula To Prevent Gas Migration Problems in HT/HP Wells

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