Engineering Solid Particulate Diverter to Control Fracture Complexity: Experimental Study

Gomaa, Ahmed M.; Nino-Penaloza, Andrea; McCartney, Elizabeth; Mayor, John

doi:10.2118/179144-ms

Cited by 34 publications

(7 citation statements)

References 13 publications

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“…The shale gas wells in the Fuling shale gas reservoir have exhibited a significant decline in production over time, necessitating the need for refracturing to enhance the recovery rate of the gas field [46]. In terms of temporary plugging and refracturing technology, Sinopec has conducted on-site trials at several wells in the Fuling shale gas reservoir, demonstrating the feasibility of this technology.…”

Section: Fuling Casementioning

confidence: 99%

Review of Shale Oil and Gas Refracturing: Techniques and Field Applications

Xu,

Wang,

Liu

et al. 2024

Processes

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Shale oil and gas wells usually experience a rapid decline in production due to their extremely low permeability and strong heterogeneity. As a crucial technique to harness potential and elevate extraction rates in aged wells (formations), refracturing is increasingly employed within oil and gas reservoirs globally. At present, the selection processes for refracturing, both of wells and layers, are somewhat subjective and necessitate considerable field data. However, the status of fracturing technology is difficult to control precisely, and the difference in construction effects is large. In this paper, well selection, formation selection, and the fracturing technology of shale oil and gas refracturing are deeply analyzed, and the technological status and main technical direction of refracturing technology at home and abroad are analyzed and summarized. The applicability, application potential, and main technical challenges of existing technology for different wells are discussed, combined with the field production dynamics. The results show that well and layer selection is the key to the successful application of refracturing technology, and the geological engineering parameters closely related to the remaining reservoir reserves and formation energy should be considered as the screening parameters. General temporary plugging refracturing technology has a low cost and a simple process, but it is difficult to accurately control the location of temporary plugging, and the construction effect is very different. Mechanical isolation refracturing technology permits the exact refurbishment of regions untouched by the initial fracturing. However, it is costly and complex in terms of construction. Consequently, cutting the costs of mechanical isolation refracturing technology stands as a pivotal research direction.

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Section: Fuling Casementioning

confidence: 99%

Review of Shale Oil and Gas Refracturing: Techniques and Field Applications

Xu,

Wang,

Liu

et al. 2024

Processes

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“…In contrast, there are relatively few experimental studies on the temporary plugging of perforations, in which there are large discrepancies between the simulation of perforations and actual perforations [6]. The widely adopted method to simulate the perforation is to make a circular hole in the center of the metal plate and consider this hole as the perforation [15][16]. Based on this, a metal simulated perforation with a small core column size and a circular platform-like channel inside the metal to simulate a wedgeshaped perforation shape [17].…”

Section: Introductionmentioning

confidence: 99%

Experimental study of the temporary plugging pattern of perforations by multi-particle size composites

Zhang¹,

Tang²,

Du³

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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In the process of temporary plugging and diverting fracturing of horizontal wells, the seating of large-size temporary plugging balls on the perforation is unstable and the plugging efficiency of irregular perforations is low, so a smaller-size composite temporary plugging agent is needed to improve the temporary plugging efficiency. In this study, based on the actual situation of Changqing oilfield, three kinds of temporary plugging materials with small particle sizes were used to plug the perforation. A simulated perforation plugging device with different permeability was built by artificial cores, and the plugging law and pressure-bearing capacity of the composite temporary plugging materials inside the perforation were studied. The results show that the temporary plugging materials with particle sizes smaller than the diameter of the perforation can form a plug inside the perforation, and the plugging zone formed inside the perforation is discontinuous. The plugging zone has good pressure-bearing performance, and the indoor blocking pressure is more than 15 MPa. The orthogonal experiments showed that the importance of three kinds of temporary plugging agents in the composite temporary plugging materials were 3-4 mm particles, 0.15 mm powder, and 1-2 mm particles, and the optimal ratio is 3:3:2. This study provides a technical basis for the design of the temporary plugging and diverting fracturing.

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“…Acid is usually injected in stages separated by nonreactive (i.e., pad) fluid injection. These nonreactive stages could also contain diverters to reduce fluid loss and plug natural fractures. , …”

Section: Introductionmentioning

confidence: 99%

“…These nonreactive stages could also contain diverters to reduce fluid loss and plug natural fractures. 4,5 Performance prediction of acid fracturing operations is necessary to optimize the design. 2 Conventionally, computational models were developed to estimate the acid penetration distance and fracture conductivity.…”

Section: ■ Introductionmentioning

confidence: 99%

An Artificial Intelligence-Based Model for Performance Prediction of Acid Fracturing in Naturally Fractured Reservoirs

2021

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Acid fracturing is one of the most effective techniques for improving the productivity of naturally fractured carbonate reservoirs. Natural fractures (NFs) significantly affect the design and performance of acid fracturing treatments. However, few models have considered the impact of NFs on acid fracturing treatments. This study presents a simple and computationally efficient model for evaluating acid fracturing efficiency in naturally fractured reservoirs using artificial intelligence-based techniques. In this work, the productivity enhancement due to acid fracturing is determined by considering the complex interactions between natural and hydraulic fractures. Several artificial intelligence (AI) techniques were examined to develop a reliable predictive model. An artificial neural network (ANN), a fuzzy logic (FL) system, and a support vector machine (SVM) were used. The developed model predicts the productivity improvement based on reservoir permeability and geomechanical properties (e.g., Young’s modulus and closure stress), natural fracture properties, and design conditions (i.e., acid injection rate, acid concentration, treatment volume, and acid types). Also, several evaluation indices were used to evaluate the model reliability including the correlation coefficient, average absolute percentage error, and average absolute deviation. The AI model was trained and tested using more than 3100 scenarios for different reservoir and treatment conditions. The developed ANN model can predict the productivity improvement with a 3.13% average absolute error and a 0.98 correlation coefficient, for the testing (unseen) data sets. Moreover, an empirical equation was extracted from the optimized ANN model to provide a direct estimation for productivity improvement based on the reservoir and treatment design parameters. The extracted equation was evaluated using validation data where a 4.54% average absolute error and a 0.99 correlation coefficient were achieved. The obtained results and degree of accuracy show the high reliability of the proposed model. Compared to the conventional simulators, the developed model reduces the time required for predicting the productivity improvement by more than 60-fold; therefore, it can be used on the fly to select the best design scenarios for naturally fractured formations.

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Engineering Solid Particulate Diverter to Control Fracture Complexity: Experimental Study

Cited by 34 publications

References 13 publications

Review of Shale Oil and Gas Refracturing: Techniques and Field Applications

Review of Shale Oil and Gas Refracturing: Techniques and Field Applications

Experimental study of the temporary plugging pattern of perforations by multi-particle size composites

An Artificial Intelligence-Based Model for Performance Prediction of Acid Fracturing in Naturally Fractured Reservoirs

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