Upscaling for Unconventional Simulation Modelling: Barik Tight Gas Formation, Khazzan Field, Block 61, Sultanate of Oman

Owolabi, O.O.; Sebastian, Herbert M.; Dawson, William C.; Rashdi, Khalil Al; Spain, David R.; Yuan, Changxia

doi:10.2118/183468-ms

Day 2 Tue, November 08, 2016 2016

DOI: 10.2118/183468-ms

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Upscaling for Unconventional Simulation Modelling: Barik Tight Gas Formation, Khazzan Field, Block 61, Sultanate of Oman

O.O. Owolabi¹,

Herbert M. Sebastian²,

William C. Dawson³

et al.

Abstract: In this study, various upscaling techniques and their effects on Barik tight gas Formation simulation modelling results were investigated. The intent of this upscaling study is to recommend coarse models that provide approximately the same flow behavior or well performance as the fine grid model. The study will help to develop an awareness of the range of applicability for the upscaled coarse models. It will also allow coarse grid models to be used appropriately and with greater confidence in production optimi… Show more

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Cited by 2 publications

References 12 publications

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Predicting the Performance of Tight Gas Reservoirs

Alem

Baig²,

Muggeridge

et al. 2019

SPE Europec Featured at 81st EAGE Conference and Exhibition

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Engineers need to predict the production characteristics from hydraulically fractured wells in tight gas fields. Decline curve analysis (DCA) has been widely used over many years in conventional oil and gas fields. It is often applied to tight gas, but there is uncertainty regarding the period of production data needed for accurate prediction. In this paper decline curve analysis of simulated production data from models of hydraulically fractured wells is used to to develop improved methods for calibrating decline curve parameters from production data. The well models were constructed using data from the Khazzan field in Oman. The impact of layering, permeability and drainage area on well performance is also investigated. The contribution of each layer to recovery and the mechanisms controlling that contribution is explored. The investigation shows that increasing the amount of production data used to fit a hyperbolic decline curve does not improve predictions of recovery unless that data comes from many years (20 years for a 1mD reservoir) of production. This is because there is a long period of transient flow in tight gas reservoirs that biases the fitting and results in incorrect predictions of late time performance. Better predictions can be made by estimating the time at which boundary dominated flow is first observed (tb), omitting the preceding transient data and fitting the decline curve to a shorter interval of data starting at tb. For single layer cases, tb can be estimated analytically using the permeability, porosity, compressibility and length scale of the drainage volume associated with the well. Alternatively, tb can be determined from the production data allowing improved prediction of performance from 2-layer reservoirs provided that a) there is high cross-flow or b) there is no cross-flow and the lower permeability layer either does not experience BDF during the field life time or it is established quickly.

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Predicting the Performance of Tight Gas Reservoirs

Alem

Baig²,

Muggeridge

et al. 2019

SPE Europec Featured at 81st EAGE Conference and Exhibition

View full text Add to dashboard Cite

show abstract

Seismic Models of the Barik Reservoir

Gangopadhyay¹,

Kumar²

2022

Day 3 Wed, March 23, 2022

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Seismic modeled responses for known geological models, often using well logs, help interpret field seismic data for reservoir characterization. The seismic response of the Barik reservoir is investigated based on its properties as revealed by well logs. The porous Middle Barik manifests itself on the synthetic seismic data within the relevant bandwidth of the available seismic. In the Extended Elastic Impedance domain, chi projections of +30 and -60 appear to separate sand from shale lithology, and relatively high from low porosity in the Barik reservoir, respectively. Various models of the Barik reservoir are also built. These include ones with varying rock properties, thicknesses, and porosity. In the models with varying rock properties, the AVO signature of the Barik sand changes from class IV when the change in Vp/Vs ratio at the interface is weak, to class II or III in other cases. Effects of changes in fluid type are negligible, although a gas charged Barik sand exhibit strong AVO intercept and gradient amplitudes. The AVO behavior of the Barik sand is also dependent on its thickness. A thicker Barik sand shows class IV AVO with a strong negative intercept and positive gradient, whereas one that is half as thick displays class II AVO with a weak negative intercept and negative gradient. The porosity of the Barik sand influences its AVO behavior. The insitu and relatively low porosity Barik sand show class IV AVO with a sharply decreasing gradient for tighter Barik, whereas a higher porosity Barik sand showed a stronger gradient. Lastly, the frequency-dependent AVO signature of the Barik reservoir is investigated. The analysis revealed that the fluid signature is indistinguishable at 20 Hz but may be distinguished at 30 Hz.

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Upscaling for Unconventional Simulation Modelling: Barik Tight Gas Formation, Khazzan Field, Block 61, Sultanate of Oman

Cited by 2 publications

References 12 publications

Predicting the Performance of Tight Gas Reservoirs

Predicting the Performance of Tight Gas Reservoirs

Seismic Models of the Barik Reservoir

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