Temperature Transient Analysis in a Horizontal, Multi-zone, Intelligent Well

Muradov, Khafiz; Davies, David Roland

doi:10.2118/150138-ms

Cited by 17 publications

(5 citation statements)

References 28 publications

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“…We propose an inverse modeling approach, which examines the use of temperature transient data and the concept of a thermal skin to estimate oil shale grade and decomposition parameters. Similar to pressure transient analyses, temperature transient analyses have been used in oil and gas reservoir engineering to determine productivity, transport properties, and the vertical formation structure (Bahrami and Siavoshi, 2007;Muradov and Davies, 2012;Onur and Cinar, 2017;Sui et al, 2012). In this study, we observe heater temperature as a system response during insitu pyrolysis of oil shale in a kerogen-bearing system.…”

Section: Introductionmentioning

confidence: 99%

Estimating the reaction parameters of oil shale pyrolysis and oil shale grade using temperature transient analysis and inverse modeling

Lee

Finsterle²,

Moridis

2018

Journal of Petroleum Science and Engineering

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Grade of oil shale and reaction parameters of in-situ pyrolysismust be identified for the prediction of productivity before actual heating and production. Identification of oil shale grade and reaction parameters depends on laboratory experimentson core samples. However, laboratory-determined parameters can be different from those representing in-situ reservoir conditions. In this study, we use inverse modeling to determine oil shale grade and reaction parameters. The inversions are based on a forward model that simulates heat injection into a well. Temperature at the heating well is affected by a thermal skin effect as a result of a decrease of composite thermal conductivity around the heater due to the decompositioninduced porosity increase. Synthetic observations of heater temperature are generated from a forward simulation. Temperature difference and its derivative are used in synthetic inversions to estimate oil shale grade and parameters of active decomposition reactions with an error below 1%. The proposed methodology of inverse modeling is expected to successfully estimate the oil shale grade and reaction parameters without core sampling and subsequent surface experiments.

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Section: Introductionmentioning

confidence: 99%

Estimating the reaction parameters of oil shale pyrolysis and oil shale grade using temperature transient analysis and inverse modeling

Lee

Finsterle²,

Moridis

2018

Journal of Petroleum Science and Engineering

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“…They indicated that trasient temperature can be more informative than pressure due to its sensitivity to damage radius and permeability. Finally the transient zonal flow rates can be assumed constant during the transient because their fluctuations have only second order impact on temperature signals (Muradov and Davies 2012). Valiullin highlighted the importance of Temperature Transient Analysis (TTA) especially when the barothermal effect (transient fluid compression/expansion at early times) takes place for well test analysis (Valiullin, Ramazanov et al 2009).…”

mentioning

confidence: 99%

Modeling and Analysis of Temperature Transients Caused by Step-Like Change of Downhole Flow Control Device Flow Area

Silva

Muradov²,

Carvalho

2012

SPE Latin America and Caribbean Petroleum Engineering Conference

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Evolution and wide-spreading of downhole monitoring systems has increased a lot over the last few years. Particularly downhole temperature data has been recognized as an important input for real-time production optimization. Whereas distributed temperature analysis and interpretation are the only methods used now, temperature evolution with time offers an excellent new source of information not yet fully understood. Simulation and analysis of temperature transients in wells are therefore a promising research area at the initial stage of development.Near wellbore multiphase flow simulation considering heat transfer is not a simple task. There are aspects such as wellreservoir mutual influence where transient analysis needs to be considered. Neglecting thermal effects and completion design will result in inaccuracies of the physical phenomena representation.This paper describes a non-isothermal dynamic well-reservoir simulator taking into account the presence of flow control valves in the wellbore. A fully coupled approach was used to solve the problem. The proposed model studied is two dimensional for the reservoir and one dimensional for the well. The reservoir is considered homogeneous, anisotropic and twophase (oil/water or gas/liquid) saturated with the initial pressure above the bubble point. The well is vertical and the multiphase drift-flux model considering the radial influx is used to describe the flow in the wellbore.Case studies for three-zone intelligent wells are analyzed from transient temperature profiles generated by the simulator. A single phase is used as a base case for the two-phase case. This paper shows that temperature transients from a step-change in production rate are able to provide full well-test equivalent information about each production zone. A downhole flow control valve step-change is also analyzed as a feasibility study of a well test without zonal shut-in. Restrictions of the simulator are presented and discussed for an appropriate use of the results.

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“…Wellbore heat transfer has been a subject of study in the oil and gas industry over the past decades and gained special attention in recent years due to the improvement in temperature measurement technologies. Downhole temperature monitoring devices can now provide high accuracy and a resolution better than 0.01 K (Duru and Horne, 2011a;Muradov and Davies, 2012;Sidorova et al, 2015).…”

Section: Literature Reviewmentioning

confidence: 99%

Analytical Models for Thermal Wellbore Effects on Pressure Transient Testing

GALVAO¹

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This work presents a new coupled transient-wellbore/reservoir thermal analytical model, consisting of a reservoir/casing/tubing combined system. The analytical solutions consider flow of a slightly compressible, single-phase fluid in a homogeneous infinite-acting reservoir system and provide temperature-and pressure-transient data for drawdown and buildup tests at any gauge location along the wellbore, accounting for Joule-Thomson, adiabatic fluid-expansion, conduction and convection effects. The wellbore fluid mass density is modeled as a function of temperature and the analytical solution makes use of the Laplace transformation to solve the transient heat-flow differential equation, accounting for a rigorous transient wellbore-temperature gradient ⁄. Regarding pressure transient analysis (PTA), thermal impacted pressure data may lead to the interpretation of false geological heterogeneities, since the heat loss during the buildup period provides an increase in the pressure exerted by the wellbore-fluid column, due to an increase in the oil mass density, and a change in tubing length, consequently causing a change in the gauge location. These effects can make a homogeneous reservoir be wrongly interpreted as a double-porosity reservoir, yielding invalid conclusions to geological modeling. Results are compared to the response of a commercial non-isothermal simulator and thermal impacts on PTA interpretations are thoroughly investigated. In addition, a field case study is also provided to verify the proposed analytical solutions. The proposed model provides more accurate transient temperature flow profiles along the wellbore when compared to previous models in Literature.

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Temperature Transient Analysis in a Horizontal, Multi-zone, Intelligent Well

Cited by 17 publications

References 28 publications

Estimating the reaction parameters of oil shale pyrolysis and oil shale grade using temperature transient analysis and inverse modeling

Estimating the reaction parameters of oil shale pyrolysis and oil shale grade using temperature transient analysis and inverse modeling

Modeling and Analysis of Temperature Transients Caused by Step-Like Change of Downhole Flow Control Device Flow Area

Analytical Models for Thermal Wellbore Effects on Pressure Transient Testing

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