期刊,Journal of Petroleum Science & Engineering 2022年208PA卷期_国家学术搜索

期刊信息/Journal information

Journal of Petroleum Science & Engineering

Elsevier Science B.V.

主办单位：Elsevier Science B.V.

国际刊号：0920-4105

Journal of Petroleum Science & Engineering/Journal Journal of Petroleum Science & Engineering

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Feasibility study for seismic monitoring of hydrocarbons using dipole sonic logs

Jorge S. MendozaMariano Floricich

12页

查看更多>>摘要：This study will determine the feasibility of using the changing elastic parameters of reservoir rocks to infer changes in fluids saturation, pressures, and temperatures during the production phase. These changes may be detected via seismic records at several production time windows. Previous works in this area involved measuring a well core's elastics properties in the lab, which limits the method to where core data is available. In this study, full-waveform acoustic logs have been used to compute the elastic properties of reservoir rocks. The use of this kind of log produces a more abundant set of elastic parameters over a broader depth interval, which better represents the real conditions of the reservoir. These data, along with the fluid flow simulation model, were used to construct maps for the elastic properties in saturated media, via Gassmann (1951) relationships and Biot (1956) theory. The methodology has been applied to the Santa Barbara field located in eastern Venezuela. The Santa Barbara field is a gas and oil productive field. The results have been compared favorably to those obtained in previous work using only well core data.

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The combustion performance and kinetics of Saray-Thrace region coal;; The effects of particle size and heating rate

Mustafa Versan KokBetul Yildirim

8页

查看更多>>摘要：This research aimed at understanding the effects of particle size and heating rate on combustion characteristics and kinetics of Saray-Thrace region coal by performing thermogravimetry (TG-DTG) analysis. The TG-DTG curves revealed two main reaction regions for each heating rate studied (5,10, and 15 C/min, particularly the evaporation of moisture and carbonization stages. The reaction intervals extended while the corresponding peak and burn-out temperatures increased as the heating rate was increased. Furthermore, a slight delay occurred in burn-out temperatures while the peak temperatures mostly increased with increased particle size, which is correlated with the decrease in surface area. On the other hand, the average mass loss percentages in carbonization stages mostly increased with increased particle size. Similarly, the combustion performance and reactivity of coal samples, which were evaluated through the values of combustion performance index (S), maximum reactivity (Rmax), and ignition index (D), suggested that the larger the particle size and the higher the heating rate, the better the combustion activity. The kinetic analysis of coal samples was also performed using model-free (iso-conversional) methods, particularly the Ozawa-Flynn-Wall (OFW) and Kissinger-Akahira-Sunose (KAS). The corresponding average activation energy (Ea) range of different size coal samples varied within the range of 62.1~(-1)91.8 kj/mol, and the lowest Ea found for the largest particle size coal sample, supported the ignition performance and reactivity results.

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NSTL

Calculation and controlled factors of hydrocarbon expulsion efficiency using corrected pyrolysis parameters;; A Songliao case study

Haitao XueZhentao DongShansi Tian

12页

查看更多>>摘要：In recent years, rock pyrolysis parameters combined with a mass balance method have been used to calculate the hydrocarbon expulsion efficiency. However, due to the experimental procedure of rock pyrolysis, the residual hydrocarbon amount (Si) is underestimated, and the hydrocarbon-generation potential of kerogen (S2) is overestimated, so that the hydrocarbon expulsion efficiency calculated from the pyrolysis parameters before correction is higher than the actual value. In this paper, the pyrolysis parameters were corrected by performing pyrolysis before and after the extraction of source rocks, and the hydrocarbon expulsion efficiency of the mudstone of the Qing 1 member of the Hal4 well in Songliao basin was calculated using the chemical kinetics method. The hydrocarbon expulsion efficiencies before and after the correction were considerably different, the hydrocarbon expulsion efficiency of the Hal4 well after correction was 17.5% lower than that before correction. The study show that the higher the abundance and maturity of source rock are, the higher the hydrocarbon expulsion efficiency is;; the oil-type organic matter has a higher hydrocarbon-expulsion efficiency than the gas-type organic matter;; the interbedded sand and mud type source-reservoir configuration relationship is beneficial to hydrocarbon expulsion;; the underwater diversion channel phase has the highest hydrocarbon expulsion efficiency.

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Downhole quantitative evaluation of gas kick during deepwater drilling with deep learning using pilot-scale rig data

Qishuai YinJin YangMayank Tyagi

24页

查看更多>>摘要：Gas kick occurs frequently during deep-water drilling operations caused by the lack of safe margin between pore pressure and leakage pressure. The existing research is limited to gas kick classification and cannot quantitatively evaluate the gas kick risk in the downhole very well. Thus, the objective of this work is to systematically use Long Short-Term Memory (LSTM) Recurrent Neural Network (RNN) models based on pilot-scale rig data for quantitative evaluation of gas kick risk. Furthermore, the quantitative evaluation is not surface but downhole. First, the gas kick simulation experiment is accomplished in the pilot-scale test well and produces the gas kick dataset, which is based on the multi-source data fusion through the surface monitoring technologies, riser monitoring technologies and downhole monitoring technologies. Second, the training features are selected and grouped as Setsl-5 to study the features' sensitivity. Third, the raw data is processed and prepared for the following machine learning framework. Fourth, there are five (5) LSTM models trained on Setsl-5. The results indicate that the models' Loss decrease with the increase of feature number, which has fully demonstrated the effectiveness of PWD, EKD, and Doppler parameters. Finally, there are four representative case studies (artificial gas kick) that are used to test the above five models. The compressed air injected rate (AR) prediction error and detection time-delay decrease with the increase of feature number. The LSTM model trained with the combination of surface-riser-downhole comprehensive detection technologies performs the best in reducing both the prediction error and detection time delay, which could be used to quantitatively evaluate the downhole gas kick risk in the more accurate, faster, more stable, more reliable, and cost-effective manner, and it is effective and worthy of promotion.

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NSTL

Fracture mechanism and damage characteristics of coal subjected to a water jet under different triaxial stress conditions

Zhaolong GeShirong CaoYiyu Lu

15页

查看更多>>摘要：Coalbed methane (CBM) recovery using water jet drilling is regarded as a promising technology for high-efficiency, heat-free, and environmentally-friendly development of deep resources. An investigation of the fracture mechanism of coal subjected to a water jet under triaxial stress is essential for the future application of this technology in a deep environment. In this study, the fracture mechanism was discussed, and laboratory experiments were conducted on coal breaking with a water jet under triaxial stress conditions for the first time. The results indicate that there are distinct fracture patterns with/without triaxial stress. With the increase of triaxial stress, the main component of coal failure transitions from tensile failure due to the water wedge to shear failure due to water hammer pressure. The rock-breaking ability of the water jet was impaired significantly under triaxial stress conditions. The tensile fracture zone induced by the water jet was concentrated in the range of 60° of the maximum principal stress direction. Computed tomography (CT) scanning tests were used to document the fracture morphology inside the coal specimens. CT scanning showed that the cracks around the hole were deflected into the direction of maximum principal stress, and the area of the damage caused by the jet decreased with increasing triaxial stress. Three-dimensional (3D) reconstructions of the impacted coal were established based on slice images for visualization. The results revealed that the weak planes in the coal and the triaxial stress were the dominant factors affecting the damage characteristics. When the average stress increased 5 MPa, the radial damage range decreases approximately 58%, and the axial damage range decreases approximately 57%. The damage is concentrated in the jet impact area. These findings provide a reference for the application of water jet technology in deep CBM recovery.

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Study on the viscoelastic-thixotropic characteristics of waxy crude oil based on stress loading

Liping GuoXiao XuYun Lei

10页

查看更多>>摘要：High waxy crude oil occupies an important proportion in oil resources, and its output is increasing year by year. At the temperature below the wax precipitation point, the wax in crude oil will precipitate and crosslink to form a spatial network structure, resulting in the gelation of crude oil. Once crude oil is gelled, it will exhibit viscoelastic-thixotropic characteristics, which will seriously affect the safety of crude oil pipeline transportation. In this paper, based on the principle of mechanical analogy, the elasticity, viscosity and structural strength of the gelled crude oil are characterized by springs, viscous pots, and structural parameters, respectively. On this basis, the viscoelastic-thixotropic model of waxy crude oil with 9 parameters is established. Meanwhile, the model applicability is verified by experimental data using two waxy crude oils under constant shear stress, shear stress step increase and shear stress hysteresis. Compared with the models in literatures, our model has clear physical meaning, relatively few parameters and high prediction accuracy.

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NSTL

Experimental investigation on the breakdown pressure and fracture propagation of radial borehole fracturing

Shouceng TianQingling LiuZhaoquan Guo

11页

查看更多>>摘要：Radial borehole fracturing is a technology combing hydraulic fracturing and slender boreholes which are radially drilled from the main wellbore by water jets. This paper aims to investigate how the radial boreholes influence the fracture extension when they are pressurized by the fracturing fluids. Concrete blocks containing radial boreholes were cast, the mechanical properties of such blocks were tested, and these samples were hydraulically fractured through a laboratory tri-axial fracturing apparatus. Experimental results show that increasing the azimuths of the radial boreholes enhances the breakdown pressures, but it will reduce the fracture extension distances (deviation distances) paralleling to the radial borehole axes. Similar trends appear when the horizontal stress differences diminish and the distances between adjacent layers of radial borehole axes increase. When changing the numbers of the radial boreholes, the variations of the breakdown pressures depend on the layouts of the radial boreholes. Besides, increasing the pump rates lifts the breakdown pressures and enhances the deviation distances. Compared to perforation fracturing, radial borehole fracturing has higher breakdown pressures and stronger control to fracture propagation. It is concluded that the extrusion forces exist in the horizontal zones between the radial boreholes. A conceptual model is proposed which can explain the variations of the deviation distances. When the injection time of the fracturing fluids is identical, the higher breakdown pressures will decrease the deviation distances because of the extrusion forces. There is a balance between the lower breakdown pressures and the higher pore pressures both caused by the more penetration of the fracturing fluid, which can either increase the deviation distances or reduce the deviation distances.

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Prediction of porous media fluid flow using physics informed neural networks

Muhammad M. AlmajidMoataz O. Abu-AI-Saud

17页

查看更多>>摘要：Due to the explosion of the digital age of data, deep learning applications for different physical sciences have gained momentum. In this paper, we implement a physics informed neural network (PINN) technique that incorporates information from the fluid flow physics as well as observed data to model the Buckley-Leverett problem. The classical problem of drainage of gas into a water-filled porous medium is used to validate our implementation. Several cases are tested that signify the importance of the coupling between observed data and physics-informed neural networks for different parameter space. Our results indicate that PINNs are capable of capturing the overall trend of the solution even without observed data but the resolution and accuracy of the solution are improved tremendously with observed data. Adding a small amount of diffusion to the PDE-constrained loss function improved the solution slightly only when observed data were used. Moreover, the PINN is used to solve the inverse problem and infer the most optimal multiphase flow parameters. The performance of the PINN is compared to that of an artificial neural network (ANN) without any physics. We show that the ANN performs comparably well to the PINN when the observed data used to train the ANN include times that span the early-and late-time behavior. As opposed to the PINN, the ANN is not able to predict the solution when only early-time saturation profiles are provided as observed data and extrapolation are needed.

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Pore-throat structure characteristics of tight reservoirs of the Middle Permian Lucaogou formation in the Jimsar Sag, Junggar Basin, northwest China

Xiaojun WangYong SongXuguang Guo

15页

查看更多>>摘要：The Middle Permian Lucaogou Formation in the Junggar Basin, China is a typical tight oil reservoir. Thin sections, helium porosity and permeability, X-ray diffraction, X-ray computed tomography, and focused ion beam scanning electron microscopy were used to analyze 11 core samples with different oiliness from the Lucaogou Formation. Muddy siltstone, tuffaceous siltstone, dolomitic siltstone, and sandy dolarenite are the primary rock types in the Lucaogou tight oil reservoirs with different oil saturations. The dolomite content of the Lucaogou tight reservoir is positively correlated with porosity and permeability, suggesting that dolomite has an important influence on reservoir quality. Sandy dolarenite and dolomitic siltstone are characterized by a high dolomite content with the largest pore and throat radii and have a higher pore-throat network connection ratio with higher permeability and better oiliness. Thus, the quality of the Lucaogou tight reservoir is primarily controlled by the dolomite content.

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Performance evaluation of machine learning-based classification with rock-physics analysis of geological lithofacies in Tarakan Basin, Indonesia

Gian AntariksaRadhi MuammarJihwan Lee

18页

查看更多>>摘要：This study aims to put a supervised learning method for automatically classifying lithofacies in well-logging dataset, where several machine learning algorithms were compared in this study that took place in the Tarakan Basin, Indonesia. The predicted lithofacies in this study including shale, shaly sandstone, sandstone, and coal, where coal is considered as the unique lithofacies in the study area. As training and testing datasets, we used two separate well log datasets from the Tarakan Basin. The first well, named Omnicron, was used to train the model, while the second well, named Kay, was used to test it. Random Forest and Gradient Boosting outperformed the other models in the experiment, with the accuracy of 87.49% and 87.01%, respectively. When it came to classifying coal, however, both approaches had issues. The Pr-Recall curve revealed that the coal score was under average precision in each facies, with values of roughly 0.52 and 0.38, respectively, which explaining why, even with high accuracy, the machine learning algorithm predicted poorly in one lithofacies class. In order to evaluate this coal misclassification, we used rock physics to analyze the machine learning prediction in this report. As result, we found that each facies is well-differentiated by physical properties, and the predicted lithofacies have a distribution that is close to the original facies however, coal may be potentially misclassified as other lithofacies as some of the coals have similar rock physical properties with the surrounding lithology (e.g. coal with a mixture of shale may have similar DT and GR responses). Based on this research, the use of machine learning in the Tarakan Basin effectively provides lithofacies data with a high degree of precision and accuracy in a much shorter time.

原文链接:

NSTL