Comparison of Numerical vs Analytical Models for EUR Calculation and Optimization in Unconventional Reservoirs

Moinfar, Ali; Erdle, James C.; Patel, K.

doi:10.2118/180974-ms

Cited by 4 publications

(1 citation statement)

References 26 publications

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“…Inversion algorithms that rely on analytic models in lieu of 3-D reservoir models see a dramatic improvement in computation speed (Moinfar et al 2016).…”

Section: Inclusion Of Analytic Models In Inversion -mentioning

confidence: 99%

Characterization of Multiple Transverse Fracture Wells Using the Asymptotic Approximation of the Diffusivity Equation

Malone

King

Wang

2019

SPE Europec Featured at 81st EAGE Conference and Exhibition

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Rate transient analysis using log-log plots of rate-normalized pressure (RNP) and its derivative (RNP') versus material balance time have proven helpful in providing estimates of shale matrix permeability and SRV drainage volumes in multiple transverse fracture wells (MTFW's) (Samandarli et al. 2012). The calculation of these properties requires the accurate detection and definition of the "end of linear flow" (telf) – the time at which hydraulic fractures begin to draw down upon their neighbors, causing the onset of what Song and Ehlig-Economides (2011) have described as "pseudo pseudo steady state" flow. The definition of telf is currently ambiguous, and in this study, we quantify and clarify the numerical definition of telf and the physical mechanisms behind its use as a permeability and drainage volume estimator. We have constructed an analytical model of MTFW's that accurately predicts individual fracture flow performance for both constant and variable rate and constant bottom hole pressure inner boundary conditions. Using this model, we can accurately compute the pressure disturbance and rate change seen at the whole well and for individual fractures to quantify the degree of interference between fractures for any number of parallel, equally-spaced, and equally-sized fractures. This model has been validated by simulation using a commercial simulator. With both this analytical model and a series of numerical simulations, we investigated the fundamental mechanisms of flow in MTFW's and how the estimation of telf may be improved. Previous authors have represented the progression of flow regimes in MTFW's as a linear flow period that transitions to a pseudo steady state (or apparently boundary-dominated) flow regime. We show that the same flow response is exhibited by a fully-infinite linear system, calling into question the nature of the "stimulated reservoir volume" (SRV) as a bounded reservoir system. In addition, we show telf can be detected and interpreted as the beginning of the onset of this fracture interference using the "limit of detectability" concept.

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“…Inversion algorithms that rely on analytic models in lieu of 3-D reservoir models see a dramatic improvement in computation speed (Moinfar et al 2016).…”

Section: Inclusion Of Analytic Models In Inversion -mentioning

confidence: 99%

Characterization of Multiple Transverse Fracture Wells Using the Asymptotic Approximation of the Diffusivity Equation

Malone

King

Wang

2019

SPE Europec Featured at 81st EAGE Conference and Exhibition

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Introduction and literature review

Tripoppoom¹,

Yu²,

Sepehrnoori³

et al. 2021

Assisted History Matching for Unconventional Reservoirs

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Dynamic Physics-Guided Deep Learning for Production Forecasting in Unconventional Reservoirs

Razak

Cornelio

Cho

et al. 2023

SPE Western Regional Meeting

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Neural network predictive models are popular for production forecasting in unconventional reservoirs. They have the ability to learn complex input-output mapping between well properties and observed production responses from the large amount of data collected in the field. Additionally, the flow behavior in hydraulically fractured unconventional reservoirs is not well understood making such statistical models practical. Variants of neural networks have been proposed for production prediction in unconventional reservoirs, offering predictive capability of varying levels of granularity, accuracy and robustness against noisy and incomplete data. Neural network predictive models that incorporate physical understanding are especially useful for subsurface systems as they provide physically sound predictions. In this work, we propose a new Dynamic Physics-Guided Deep Learning (DPGDL) model that incorporates physical functions into neural networks and uses residual learning to compensate for the imperfect description of the physics. The new formulation allows for dynamic residual correction, avoids unintended bias due to less-than-ideal input data, and provides robust long-term predictions. The DPGDL model improves upon a static formulation by utilizing a masked loss function to enable learning from wells with varying production lengths and by improving the results when partially-observed timesteps are present. We also develop a new sequence-to-sequence residual model to correct additional biases in the long-term predictions from the physics-constrained neural networks. Several synthetic datasets with increasing complexity as well as a field dataset from Bakken are used to demonstrate the performance of the new DPGDL model.

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Comparison of Numerical vs Analytical Models for EUR Calculation and Optimization in Unconventional Reservoirs

Cited by 4 publications

References 26 publications

Characterization of Multiple Transverse Fracture Wells Using the Asymptotic Approximation of the Diffusivity Equation

Characterization of Multiple Transverse Fracture Wells Using the Asymptotic Approximation of the Diffusivity Equation

Introduction and literature review

Dynamic Physics-Guided Deep Learning for Production Forecasting in Unconventional Reservoirs

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