Improving Hydrocarbon/Water Ratios in Producing Wells - An Indonesian Case History Study

Stanley, F.O.; Hardianto,; Marnoch, Ewen; Tanggu, Paternus Syukur

doi:10.2118/36615-ms

Cited by 13 publications

(5 citation statements)

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“…And indeed, a lot of case history results (Refs. 33,34,35,36) support this observation. Total productivity of the wells has declined in all cases.…”

Section: A Fact About Rpm (It Does Not Mitigate Water Production Fromsupporting

confidence: 56%

Chemical Water & Gas Shutoff Technology - An Overview

Kabir¹

2001

Proceedings of SPE Asia Pacific Improved Oil Recovery Conference

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractNumerous chemical options are available for addressing excessive water and gas production problems. The chemistry of most of these options is complicated. A petroleum engineer with an average chemistry background has difficulties understanding these to a level that enables him/her to choose and apply a proper option to the problem at hand. In this paper, we provide a brief overview of all chemical water/gas shutoff (WGSO) options available to date. Monomer systems, polymer gels, relative permeability modifying polymers, inorganic gels, plastics etc. are commonly used chemical options. Less common options include viscous flooding, selective plugging with induced mineral precipitation and other miscellaneous grouting materials. Pros and cons of all these options are also discussed. IntroductionThe need for shutting off unwanted fluid production is common to the entire spectrum of well life cycle. Drillers want to plug-off any lost circulation zone, production engineers want to shutoff any unwanted fluid producing zones in order to move to the next zone, and the asset owners want to plug & abandon any depleted wells at the end of the economic life of wells. However, a production engineer's need to control water and gas production ranges from a simple plugging operation to a more sophisticated selective reduction of permeability of an unwanted phase. A successful choice and implementation of any such technique is as demanding as the objective of the job. Therefore a need for a thorough understanding of the options available, their working mechanism, pros and cons are of paramount importance. This work is an attempt to familiarise petroleum engineers with chemical water/gas shutoff (WGSO) technology.

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“…And indeed, a lot of case history results (Refs. 33,34,35,36) support this observation. Total productivity of the wells has declined in all cases.…”

Section: A Fact About Rpm (It Does Not Mitigate Water Production Fromsupporting

confidence: 56%

Chemical Water & Gas Shutoff Technology - An Overview

Kabir¹

2001

Proceedings of SPE Asia Pacific Improved Oil Recovery Conference

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“…They discovered that the WOR and d(WOR)/dt diagnostics plots are not universal and are susceptible to being interpreted incorrectly; subsequently, they should not be utilized alone to figure out what's causing too much water production. Love et al [44] and Stanley et al [45] presented two examples of successful water treatment research design in New Mexico and Indonesia, separately. In any case, it is pivotal to take note of that in the two investigations, the WOR diagnostic plots were utilized as an enhancement to different approaches, for example, production logging and reservoir modeling, rather than as a stand-alone technique.…”

Section: Diagnostic Wor Plotsmentioning

confidence: 99%

Diagnosing and Controlling Excessive Water Production: State-of-the-Art Review

Bin Marta,

Hammouda,

Tantawy

et al. 2023

Journal of Petroleum and Mining Engineering

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The oil and gas sector faces a complex issue with excessive water production (EWP), having substantial economic and environmental consequences. The reasons that lead to EWP are called water production mechanisms (WPMs). They are classified into mechanical, completion, and reservoir problems. Each water production mechanism (WPM) needs a certain form of treatment that is suited to that situation. However, controlling water production becomes more difficult when it is related to reservoir problems. Therefore, understanding these reasons is essential to properly analyze the current situation and design the best solution for the problem. It is essential to pinpoint the problem's source first as the probability of a successful remedy is limited without a suitable diagnostic method prior to implementing a treatment strategy. Well testing and logging methods, and analytical and empirical approaches are the traditional techniques for WPM diagnosis. This paper investigated the most modern and successful strategies used to diagnose the source of EWP and suggest the proper water shutoff technique. This paper shows that the diagnostic plots derivative technique is the best way to determine the reason for EWP problems. These plots, however, should be used in conjunction with other approaches like production logging and reservoir modeling. Then, chemical, or mechanical treatment techniques can be used to stop EWP depending on the cause of the production. Mechanical techniques should typically be employed when dealing with water production management in the wellbore or adjacent to the wellbore. In contrast, chemical techniques must be utilized for matrix or fracture plugging.

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“…They reported that the WOR trends in their simulated models were in agreement with Chan's diagnostic plots and concluded that these plots could be used for problem identification in horizontal wells. Stanley et al (1996) and Love et al (1998) reported the use of WOR diagnostic plots in successful water treatment design case studies in Indonesia and New Mexico, respectively. However, it is important to notice that in both of these studies, the WOR diagnostic plots was not applied as a stand-alone technique but rather a supplementary tool with other methodologies such as production loggings and reservoir modelling.…”

Section: Diagnostic Wor Plotmentioning

confidence: 99%

Excess Water Production Diagnosis in Oil Fields Using Ensemble Classifiers

Rabiei

Gupta

Cheong

et al. 2009

2009 International Conference on Computational Intelligence and Software Engineering

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In hydrocarbon production, more often than not, oil is produced commingled with water. As long as the water production rate is below the economic level of water/oil ratio (WOR), no water shutoff treatment is needed. Problems arise when water production rate exceeds the WOR economic level, producing no or little oil with it. Oil and gas companies set aside a lot of resources for implementing strategies to effectively manage the production of the excessive water to minimize the environmental and economic impact of the produced water.However, due to lack of proper diagnostic techniques, the water shutoff technologies are not always proficiently applied. Most of the conventional techniques used for water diagnosis are only capable of identifying the existence of excess water and cannot pinpoint the exact type and cause of the water production. A common industrial practice is to monitor the trend of changes in WOR against time to identify two types of WPMs, namely coning and channelling. Although, in specific scenarios this approach may give reasonable results, it has been demonstrated that the WOR plots are not general and there are deficiencies in the current usage of these plots.Stepping away from traditional approach, we extracted predictive data points from plots of WOR against the oil recovery factor. We considered three different scenarios of pre-water production, post-water production with static reservoir characteristics and postwater without static reservoir characteristics for investigation. Next, we used tree-based ensemble classifiers to integrate the extracted data points with a range of basic reservoir characteristics and to unleash the predictive information hidden in the integrated data.Interpretability of the generated ensemble classifiers were improved by constructing a new dataset smeared from the original dataset, and generating a depictive tree for each ensemble using a combination of the new and original datasets. To generate the depictive tree we used a new class of tree classifiers called logistic model tree (LMT). LMT combines the linear logistic regression with the classification algorithm to overcome the disadvantages associated with either method.Our results show high prediction accuracy rates of at least 90%, 93% and 82% for the three considered scenarios and easy to implement workflow. Adoption of this methodology would lead to accurate and timely management of water production saving oil and gas companies considerable time and money.3

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Improving Hydrocarbon/Water Ratios in Producing Wells - An Indonesian Case History Study

Cited by 13 publications

References 0 publications

Chemical Water & Gas Shutoff Technology - An Overview

Chemical Water & Gas Shutoff Technology - An Overview

Diagnosing and Controlling Excessive Water Production: State-of-the-Art Review

Excess Water Production Diagnosis in Oil Fields Using Ensemble Classifiers

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