Theoretical Analysis of Pressure Phenomena Associated with the Wireline Formation Tester

Moran, J. H.; Finklea, Ernest E.

doi:10.2118/177-pa

Cited by 89 publications

(20 citation statements)

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“…f(⌬t) comes from the equations describing the various flow regimes. It is equal to: ⌬t for wellbore storage (Ramey 1970) and pseudosteady-state flow in closed reservoirs (Jones 1956), √⌬t for high-conductivity fracture (Clark 1968) and channel linear flows (Miller 1962;Millhein and Cichowicz 1968), 4 √⌬t for low-conductivity fracture and bilinear flow (Cinco-Ley and Samaniego 1981), 1/√⌬t for spherical flow (Moran and Finklea 1962), and log(⌬t) for radial flow in reservoirs of infinite extent (Miller et al 1950) or bounded by a sealing fault (Horner 1951) or by two no-flow intersecting faults (van Pollen 1965;Prasad 1975).…”

Section: Straight-line Analysesmentioning

confidence: 99%

From Straight Lines to Deconvolution: The Evolution of the State of the Art in Well Test Analysis

Gringarten

2008

SPE Reservoir Evaluation &Amp; Engineering

114

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Well test analysis has been used for many years to assess well condition and obtain reservoir parameters. Early interpretation methods (by use of straight lines or log-log pressure plots) were limited to the estimation of well performance. With the introduction of pressure-derivative analysis in 1983 and the development of complex interpretation models that are able to account for detailed geological features, well test analysis has become a very powerful tool for reservoir characterization. A new milestone has been reached recently with the introduction of deconvolution. Deconvolution is a process that converts pressure data at variable rate into a single drawdown at constant rate, thus making more data available for interpretation than in the original data set, in which only periods at constant rate can be analyzed. Consequently, it is possible to see boundaries in deconvolved data, a considerable advantage compared with conventional analysis, in which boundaries often are not seen and must be inferred. This has a significant impact on the ability to certify reserves.This paper reviews the evolution of well test analysis techniques during the past half century and shows how improvements have come in a series of step changes 20 years apart. Each one has increased the ability to discriminate among potential interpretation models and to verify the consistency of the analysis. This has increased drastically the amount of information that one can extract from well test data and, more importantly, the confidence in that information. IntroductionResults that can be obtained from well testing are a function of the range and the quality of the pressure and rate data available and of the approach used for their analysis. Consequently, at any given time, the extent and quality of an analysis (and therefore what can be expected from well test interpretation) are limited by the stateof-the-art techniques in both data acquisition and analysis. As data improve and better interpretation methods are developed, more and more useful information can be extracted from well test data.Early well test analysis techniques were developed independently from one another and often gave widely different results for the same tests (Ramey 1992). This has had several consequences:• An analysis was never complete because there always was an alternative analysis method that had not been tried.• Interpreters had no basis on which to agree on analysis results.• The general opinion was that well testing was useless given the wide range of possible results.Significant progress was achieved in the late 1970s and early 1980s with the development of an integrated methodology on the basis of signal theory and the subsequent introduction of derivatives. It was found that, although reservoirs are all different in terms of depth, pressure, fluid composition, geology, etc., their behaviors in well tests were made of a few basic components that were always the same. Well test analysis was about finding these components, which could be achieved in a systemati...

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Section: Straight-line Analysesmentioning

confidence: 99%

From Straight Lines to Deconvolution: The Evolution of the State of the Art in Well Test Analysis

Gringarten

2008

SPE Reservoir Evaluation &Amp; Engineering

114

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“…The sensitivity of the pressure response to the volume of trapped air is investigated using Equation (3). The results of the investigation, in which air is considered as an ideal gas, is displayed in Figure 3.…”

Section: Air Trapped In Flowlinesmentioning

confidence: 99%

Interpretation of Wireline Formation Tester (WFT) Data In Tight Gas Sands

Yildiz

Bassiouni

1999

Journal of Canadian Petroleum Technology

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This paper summarizes the analysis of wireline formation tester (WFT) data collected in tight gas sands. An interpretation algorithm based on type-curve matching is used in the analysis. The type curves are constructed using an analytical model. The model assumes hemispherical flow geometry and incorporates early time decompression period and flowline storage effect. The permeability values calculated using this algorithm agree reasonably well with the permeability values available from core measurements.

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“…The interplay between formation characteristics and tool operation is described by the following implementation of Darcy's law (Moran and Finklea, 1962;Schlumberger, 2006):…”

Section: Introductionmentioning

confidence: 99%

Improved Techniques for Acquiring Pressure and Fluid Data in a Challenging Offshore Carbonate Environment

et al. 2008

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The combination of low permeability, oil base mud and near saturated oils presents one of the most challenging environments for fluid sampling with formation testers. Low permeability indicates that the drawdown while sampling will be high but this is contra-indicated for oils that are close to saturation pressure. A logical response is to therefore reduce the flow rate but in wells drilled with OBM an unacceptably long clean-up time would result.The Pinda formation in Block 2 offshore Angola presents just such a challenge. Formation mobilities are in the low double or single-digits, saturation pressure is usually within a few hundred psi of formation pressure and borehole stability indicates that the wells must be drilled with oil base mud.In the course of several penetrations of the Pinda formation a number of attempts were made to acquire representative formation samples but were stymied due to either excessive drawdowns that corrupted the fluid or by excessive contamination levels that rendered the samples unsuitable for laboratory analysis. Clearly a more flexible solution was required.In this paper we review the learnings from previous attempts in the Pinda. We show the pre-job modeling that was done to predict the required flow rates and the anticipated drawdowns. Ultimately a two-step solution was used. We first ran a high efficiency pretest-only WFT in order to quickly gather formation pressure data and mobility data. This data was then used to design the sampling string which was a combination of an inflatable dual packer with focused probe. We discuss the decision process that governed the choice of pump, displacement unit, probe and packer. We pay particular attention to the unique pump configurations that were required to effectively manage the drawdowns when using the probe and also to allow sufficient flow rate when using the dual packer.We conclude with a summary of recommendations and lessons learned for sampling in such an environment.

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Theoretical Analysis of Pressure Phenomena Associated with the Wireline Formation Tester

Cited by 89 publications

References 0 publications

From Straight Lines to Deconvolution: The Evolution of the State of the Art in Well Test Analysis

From Straight Lines to Deconvolution: The Evolution of the State of the Art in Well Test Analysis

Interpretation of Wireline Formation Tester (WFT) Data In Tight Gas Sands

Improved Techniques for Acquiring Pressure and Fluid Data in a Challenging Offshore Carbonate Environment

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