Root-Cause Identification and Production Diagnostic for Gas Wells with Plunger Lift

Singh, Ajay

doi:10.2118/175564-ms

Cited by 7 publications

(3 citation statements)

References 16 publications

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“…Finding the splitting criteria, which depends on inputs, a DT begins, and then the value of square error between observed and calculated outputs is minimized. Thus it will have one root node and two child nodes [48]. For further splitting, the same pattern will be repeated on all child nodes.…”

Section: Methodsmentioning

confidence: 99%

A Comparison of Machine Learning Approaches for Prediction of Permeability using Well Log Data in the Hydrocarbon Reservoirs

Talebkeikhah

Sadeghtabaghi

Shabani

2021

J. Hum. Earth Future

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Permeability is a vital parameter in reservoir engineering that affects production directly. Since this parameter's significance is obvious, finding a way for accurate determination of permeability is essential as well. In this paper, the permeability of two notable carbonate reservoirs (Ilam and Sarvak) in the southwest of Iran was predicted by several different methods, and the level of accuracy in all models was compared. For this purpose, Multi-Layer Perceptron Neural Network (MLP), Radial Basis Function Neural Network (RBF), Support Vector Regression (SVR), decision tree (DT), and random forest (RF) methods were chosen. The full set of real well-logging data was investigated by random forest, and five of them were selected as the potent variables. Depth, Computed gamma-ray log (CGR), Spectral gamma-ray log (SGR), Neutron porosity log (NPHI), and density log (RHOB) were considered efficacious variables and used as input data, while permeability was considered output. It should be noted that permeability values are derived from core analysis. Statistical parameters like the coefficient of determination ( ), root mean square error (RMSE) and standard deviation (SD) were determined for the train, test, and total sets. Based on statistical and graphical results, the SVM and DT models perform more accurately than others. RMSE, SD and R2values of SVM and DT models are 0.38, 1.63, 0.97 and 0.44, 2.89, and 0.96 respectively. The results of the best-proposed models of this paper were then compared with the outcome of the empirical equation for permeability prediction. The comparison indicates that artificial intelligence methods perform more accurately than traditional methods for permeability estimation, such as proposed equations. Doi: 10.28991/HEF-2021-02-02-01 Full Text: PDF

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Section: Methodsmentioning

confidence: 99%

A Comparison of Machine Learning Approaches for Prediction of Permeability using Well Log Data in the Hydrocarbon Reservoirs

Talebkeikhah

Sadeghtabaghi

Shabani

2021

J. Hum. Earth Future

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“…Although the plunger is placed in an annular gap with the tubing as it travels upstream and creates a turbulent seal [9,10] that prevents some of the fluid from falling back down to the bottom of the well, there is still friction generated by the annular gap between the plunger and tubing in the process; since the velocity of the plunger movement in a vertical wellbore can change from moment to moment, it causes the annular gap frictional resistance to change throughout the plunger's upward travel. However, previous studies usually ignored the friction between the plunger and liquid, treating the plunger and liquid column as a single unit and considering only the friction of the liquid column.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on the Coefficient of Internal Frictional Resistance in the Annular Gap during the Plunger Gas Lift Process

Shi,

Chen,

Liao

et al. 2023

Processes

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Plunger gas lift process technology is an economical solution to the problem of gas well liquid buildup. However, in-house simulation experiments revealed that the high-speed movement of the plunger may lead to fluid leakage and generate annular gap frictional resistance. To address this issue, a detailed experimental study was conducted to comparatively analyze five existing frictional-resistance models, which were found to have significant deviations. Therefore, we propose a new model of annular gap frictional resistance and validate it with experimental data, and the results show that the new model is more accurate and reliable. We also conducted a comparative analysis of production-site examples by using VB programming and found that when considering the annular gap frictional resistance, the upward travel time of the plunger was delayed, the difference between the upper and lower end face pressures was significant, and the difference in speed was 1.73 m/s. This indicates that the annular gap frictional resistance cannot be ignored and is crucial for optimizing plunger gas lift process technology and improving the drainage efficiency of gas wells.

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“…Presently, the drainage gas production technology of shale gas wells mainly includes plunger lift, foam drainage, and gas injection lift. Among these, the plunger lift is widely used in the field because of its simple operating process, as well as low maintenance and operational costs [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Research on the Inflow Performance of the Plunger Lift in the Shale Gas Horizontal Well

Ye¹,

Tang²,

Cai³

et al. 2022

Mathematical Problems in Engineering

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Shale gas wells in the Changning block of Weiyuan, Sichuan, China, experience water production problems throughout their life cycles. In actual field production, plunger lift is typically used to discharge liquid from a shale gas well. However, it is difficult to test the formation inflow performance relationship curve (IPR) of a plunger lift well. Hence, data on the formulation and optimization of plunger lift well systems are lacking. Based on actual measured data related to casing pressure changes at the wellhead and the gas-liquid distribution characteristics in a wellbore during the shut-in phase, this paper establishes a method for calculating the formation IPR curve of a shale gas plunger lift well by calculating changes in wellbore gas volume continuously. This method has a fast calculation speed. The gas-water interface distribution can be obtained in 3–5 iterations, and the inflow dynamic curve can be calculated in less than 5 seconds. This method tested the IPR curves of gas wells in the Changning block. The IPR curves of plunger lift wells showed concave characteristics contrary to the conventional upward convex curves. This is because the bottom hole flowing pressure changes caused variations in the water saturation of the near-wellbore zone. Consequently, the productivity equation of the plunger lift well is established by introducing the variation coefficient of water saturation expressed by bottom hole flow pressure. This equation fits with the measured IPR curve with an average R2 of approximately 0.9989.

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Root-Cause Identification and Production Diagnostic for Gas Wells with Plunger Lift

Cited by 7 publications

References 16 publications

A Comparison of Machine Learning Approaches for Prediction of Permeability using Well Log Data in the Hydrocarbon Reservoirs

A Comparison of Machine Learning Approaches for Prediction of Permeability using Well Log Data in the Hydrocarbon Reservoirs

Experimental Study on the Coefficient of Internal Frictional Resistance in the Annular Gap during the Plunger Gas Lift Process

Research on the Inflow Performance of the Plunger Lift in the Shale Gas Horizontal Well

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