期刊,Journal of Petroleum Science & Engineering 2022年214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

正式出版

收录年代

An efficient, cost-effective, and green natural extract in water-based drilling muds for clay swelling inhibition

Azeem RanaMobeen MurtazaTawfik A. Saleh

8页

查看更多>>摘要：Clay swelling is one of the major challenges of the oil and gas industry during the drilling operation. Water-based muds (WBM) are commonly used in drilling operations due to their low environmental footprint. The rheologlcal properties, fluid loss control, and clay hydration play a crucial role in the selection of WBM. However, WBM can cause clay swelling in contact with clay material. For the first time, the present work reports the effect of Date palm leaves extract (DPLE) as a naturally occurring and environment-friendly green additive as a clay swelling inhibitor for water-based muds (WBM). The extensive evaluation including rheology, fluid loss, capillary suction timer (CST), zeta potential, X-ray diffraction (XRD), scanning electron microscope (SEM), and linear swelling tests were used to assess the clay swelling inhibition features of the DPLE. The outcomes revealed that the swelling control by DPLE was the function of its concentration. The 5% DPLE demonstrates the least linear swelling (62.3%) as compared to 2% DPLE (98.5%) Na2Si03 (96.5%), and water (124.2%). The DPLE also influences and improves the rheology and deflocculation properties of the WBM. The proposed inhibition mechanism shows that the surface coating of DPLE resulted in the protection of bentonite clay and make it hydrophobic. Consequently, the affordability, environment friendliness, clay swelling control, and ease of access make the pertinency of DPLE in WBM extremely worthy.

原文链接:

NSTL

A dynamic method for post buckling analysis of drill string in vertical wells

Peng JiaBo ZhouShifeng Xue

15页

查看更多>>摘要：In this paper, a dynamic method, which includes a coupled dynamic model of full-hole drill string and its numerical implementation approach, is developed to analyze the post buckling of drill string in vertical wells. The coupled dynamic model is established based on Lagrange's equations and finite difference method. Its numerical implementation approach is achieved by using the direct integration method and Rayleigh damping formula. Especially the developed dynamic method is able to consider the coupling of axial vibration, lateral vibration, torsional vibration and the effects of rotating speed, damping from the drilling fluid, the discontinuous contact and friction between drill string and borehole, which enable it to predict the post bucking behaviors of drill string in vertical wells more efficiently and accurately. The developed dynamic method is validated by the comparison with the static theoretical solution of drill string, and then it is used to calculate the dynamic post buckling of drill string in vertical wells. The calculation results show that the contact length increases with the increase of the friction coefficient when the weight on bit is stable. There are critical speeds to make the contact length take the extreme value, and the critical speeds vary with the change of weight on bit and drill string length. The increase of drill string length does not change the quasi-static contact length, but will make the dynamic contact length fluctuate greatly. The fluctuation of weight on bit and torque on bit make the contact length fluctuate near the quasi-static contact length under most weight on bit. This work provides important theoretical and technical support for the comprehensive analysis of the dynamic buckling characteristics of drill string in vertical wells.

原文链接:

NSTL

Experimental and numerical investigations of water-oil two-phase flow in fractures with proppants of different wetting properties

Ming WangYuanyuan MaHao Li

10页

查看更多>>摘要：In hydraulic fractures, proppant surface wettability is highly impact on oil and water displacement. Therefore the objective of this study is to investigate the effectiveness of proppant surface wettability when oil and water flow through the fracture. In this work, oil and water are tested to pass through sandstones, which have different permeabilities and different fracture widths. And inside fractures, proppants are varied with different size and surface wettability. The experimental results show that the more hydrophobic the proppant surface is, the more likely it has capability to hinder the water flow. Water breakthrough on oil-wet 1 proppant are 0.36 PV and 0.38 PV, respectively. Water breakthrough on oil-wet 2 proppant are 0.278 PV and 0.34 PV, respectively. Results also show that the ability of water blocking of oil-wet proppant might insignificant related to fracture width variation. Water breakthrough on oil-wet 1 proppant is 0.33 PV and on oil-wet 2 proppant is 0.36 PV. But this phenomenon needs more experiments to verify. Strong oil-wet proppant has higher tendency to make the water flow slow down, since it displays water blocking phenomenon on both sandstone samples with high permeability and low permeability. On PB-SS and UGB-SS, water breakthrough of oil-wet 1 proppants have 0.08 PV and 0.04 PV larger than that of oil-wet 2 proppants, respectively. The numerical simulation results also show the similar tendency. With the decrease of contact angle, the proppant surface displays a stronger attraction to oil. However, when the contact angle is closer to 1/2π, comparing with other groups, the hindrance effect of the proppant on the aqueous phase is not able to reach a stability tendency within the same amount of time.

原文链接:

NSTL

Experirnental investigation of multi-walled carbon nanotubes assisted surfactant/polymer flooding for enhanced oil recovery

Javad RazavinezhadArezou JafariSeyed Masoud Ghalamizade Elyaderani

14页

查看更多>>摘要：For the first time, we investigated the effect of carbon nanotube (CNT) on surfactant/polymer flooding so as to improve oil recovery and explore its mechanisms. To this end, we performed wettability, surface tension (ST), and viscosity tests. Then, micromodel flooding was performed using design of experiments (DOE) method. The results demonstrated that the surfactant/polymer (SP) solution can reduce the contact angle from 143.6° to 24°; besides, the presence of nanopardcle in the solution approximates the contact angle to zero. Also, compared to the SP solution, the surfactant/nanoparticle/polymer (SNP) solution can lead to a more strongly water-wet surface wettability. In the case of SNP, increasing nanoparticle concentration slightly increases the fluid viscosity. Additionally, at fixed concentrations of surfactant and polymer, increasing nanoparticle concentration can raise ST values. Therefore, given the relationship between increasing ST and decreasing interfacial tension (IFT), it can be inferred that the presence of carbon nanotube in the SP solution can lead to a reduction in IFT. The emulsion tests illustrated that the presence of CNT in SP solution does not alter the emulsion type (water-in-oil). The results of micromodel flooding also showed that increasing the concentration of CNT in the SP solution improves oil recovery by 5-11%. Furthermore, an optimal concentration was defined for the surfactant in SNP flooding, up to which point increasing the surfactant concentration raises oil recovery but beyond which the oil recovery diminishes. The DOE method indicated that, in descending order, the polymer, CNT, and surfactant could have the greatest impact on boosting oil recovery. In other words, under SNP flooding, polymer concentration and surfactant concentration exert the most and the least impact on increasing oil recovery.

原文链接:

NSTL

Lost circulation materials for deep and ultra-deep wells: A review

Peng XuLei PuMingbiao Xu

23页

查看更多>>摘要：The number of deep wells and ultra-deep wells drilled worldwide is gradually increasing, and the problem of deep well leakage has become one of the challenges in drilling. The high-temperature and high-pressure environment in deep formations severely test the drilling leakage control. The lost circulation material and its nature largely determine the success rate of deep well leakage control. The paper discusses the failure and instability mechanism of the lost circulation materials in deep wells and the plugging zone formed by them. The lost circulation materials are classified as physical and chemical lost circulation materials. It includes bridge plugging materials, high filtration loss plugging materials, organic gel plugging materials, expansion plugging materials, resin plugging materials, and inorganic gel plugging materials. According to the published evaluation and analysis of temperature and pressure resistance of leakage lost circulation materials, the characteristics of different types of temperature and pressure resistance leakage lost circulation materials are summarized. Based on a large number of existing researches and the practice of the team on high temperature and high-pressure leakage plugging, the research on the theory of high temperature and high-pressure leakage plugging and the research adaptability of high temperature and high-pressure resistant materials, the research on new physical and chemical temperature and pressure-resistant materials, the composite leakage plugging method and its suitability Prospects are put forward in terms of temperature and pressure plugging technology and strive to improve the success rate of loss control in deep wells.

原文链接:

NSTL

Simulation models for the minimum velocity for foam generation and propagation

G. YuW.R. Rossen

16页

查看更多>>摘要：Foam injection is a promising means of reducing the relative mobility of gas, and hence improving the sweep efficiency of gas, in CO2 and H2 storage, soil-contaminant removal in aquifer remediation, enhanced oil recovery, and matrix-acid well stimulation. Theory (Rossen and Gauglitz, 1990; Ashoori et al, 2012) and experiment (Gauglitz et al., 2002; Yu et al., 2019, 2020) indicate that both foam generation and propagation in steady flow in porous media require the attainment of a sufficiently large superficial velocity or pressure gradient P. Here we examine several foam-simulation models for their ability to represent a minimum velocity, or trigger, for foam generation. We define criteria for representation of such a trigger. For simplicity, we assume a homogeneous porous medium and absence of an oleic phase. We examine the Population-Balance (PB) models of Kam and Rossen (2003) and one of its variants (Kam, 2008), and the PB model of Chen et al. (2010); and the implicit-texture (IT) models in CMG-STARS (Computer Modeling Group, 2017) and of Lotfollahi et al. (2017). Our result show that the PB models of Kam and Rossen and its variant, and the IT models of CMG-STARS and of Lotfollahi et al. do represent a minimum velocity for foam generation. They achieve this by modeling an abrupt decrease in gas mobility with increasing pressure gradient over some range of P. The model of Chen et al. (2010) is based on the model of Kovscek and Radke (1996), which was not intended to represent a trigger for foam generation (Kovscek and Radke, 1993). We cannot say categorically whether it could predict a trigger for any set of model parameter values. Instead, we derive criteria that must be satisfied by the choice of parameters to represent a trigger for foam generation. In simulations of radial foam propagation the STARS foam model predicts that foam propagation fails at the radius at which local P cannot maintain strong foam, not at a greater velocity and P as seen in experiments (Yu et al., 2020). In addition, we identify a fundamental challenge in representing foam generation at the large P at the wellbore in a numerical simulation: conventional simulators do not represent P at the wellbore. Foam generation at the very high superficial velocity at the well radius is not represented in the absence of truly exceptional grid refinement.

原文链接:

NSTL

Experimental study on pore fluid characteristics of fractured sandstone based on nuclear magnetic resonance technology

Youlin XuXuelong LiXukun Wu

9页

查看更多>>摘要：The groundwater seepage in the fractured rock mass affects the stability of the surrounding rock of the roadway. To understand the fluid seepage characteristics and the change law of the microscopic pore structure of the fractured rock mass under different loading conditions, the low-field nuclear magnetic resonance technology (LF-NMR) was used to conduct a visual experimental study. The T2 spectrum distribution curve tested by nuclear magnetic resonance indicated that the pore structure of the fractured sandstone sample had three peaks (namely micropores, mesopores, and macropores) with medium and large pores distributed from 0.63 μm to 100 μm. Quantitative analysis of nuclear magnetic resonance imaging signals during water flooding of fractured sandstones revealed the characteristics of fluid migration and distribution at different times and locations at different flow rates in the core. The height of the fractured core at 23 mm had small water content and low porosity. The water content at the position of 25-40 mm was higher, and the porosity was large. Under the effect of flow velocity, there were obvious differences in the state of fractured core displacement. That is, the greater the flow velocity, the shorter the water flooding time and the more concentrated the fluid sweep area. The dominant channel for seepage was formed quickly. The research results can provide a reference for preventing the erosion of roadway surrounding rock caused by groundwater fluid.

原文链接:

NSTL

The role of mineralogical stratifications in controlling brine flow behavior in shale at a pore-scale perspective based on integrated imaging and compositional methods

Dengke LiuTao TianChenyang Zhao

9页

查看更多>>摘要：Pore-scale multiphase flow has always been a research hotspot petroleum engineering. However, the complexity of pore structure and the variability of the flow process have plagued researchers. More specifically, the controlling mechanisms behind mineral characteristics on brine flow behavior in shale at a pore-scale perspective are not well understood. So far, a limited number of scholars have tried to provide evidence of the underlying mechanisms based on integrated imaging and compositional methods, and the shale classification methods were mainly based on the content variation. This paper provided a new aspect concerning the mineralogical stratifications to investigate the controlling factors of movable fluid properties. Imaging and compositional techniques were used, and the samples with different mineralogical stratifications (inapparent grading sequence shale, apparent grading sequence shale, and microscopic block-shaped shale) were tested. Integrated methods showed that, compared to minerals compositions, the mineralogical stratifications would be more vital for storage capacity and fluid flow behavior in shales. Thick organic minerals bands or chunks would occlude the seepage paths, and pores below 100 nm might be the predominant storage spaces for shales. By combining the results of these methodologies, the pore size spectrum of shales can be determined more accurately. High movable fluid properties were observed for inapparent grading sequence shale. The mechanisms are discussed in terms of mineralogical stratifications and pore networks evolution Low porosity would decrease the movable fluid saturation due to the short storage spaces, and serious mineralogical stratification variations would restrict the flow path, leading to weak mobility of brine.

原文链接:

NSTL

Variable seismic waveforms representation: Weak-supervised learning based seismic horizon picking

Hao WuZhen LiNaihao Liu

14页

查看更多>>摘要：Seismic horizon picking via deep learning models have been advanced rapidly and proven popular. However, the prediction result is highly depended on the quality of the train set and the manually interpreted train set is very difficult to obtain. To guarantee a reasonable prediction result, we usually need manually interpret 20%-30% seismic data to generate the train set for the convolutional neural network (CNN) based seismic horizon picking methods, which is very time consuming. Besides, the performance of the deep learning based seismic horizon picking methods are also greatly influenced by the architecture of the selected CNN model. The core theory of using CNN for seismic horizon picking is recognizing different waveform patterns and classifying them with the corresponding labels. In this work, we first develop the variable waveform representation (VWR) algorithm to simulate the waveform features and then produce a large number of seismic traces as the train data. The VWR can deal with the task of the train set generation by only using very few seismic traces. Afterward, we propose a novel CNN model by integrating the holistically-nested module and the SegNet model for solving seismic horizon picking, which is termed as the HSegNet model. It should be noted that the holistically-nested module is able to recognize the holistic image and learn the multiple features, which is efficient for the waveform pattern recognition. To demonstrate the efficiency and robustness of our proposed HSegNet model, we apply it to field data and compare with the widely used U-Net model. The experiment results show that our proposed VWR-HSegNet can achieve the prediction result with 99% test accuracy by only manually interpreting 0.13% seismic traces. Whereas, the U-Net model can only get 91% test accuracy prediction result but using 30% manually interpreted seismic traces as the train set.

原文链接:

NSTL

Hydrocarbon potential, organisms, and depositional environments of the Lower Cambrian shales along the southern margin of the Ordos basin, Northern China

Junfeng LinJunping HuangLihong Zhang

13页

查看更多>>摘要：The dark shales of the Lower Cambrian Dongpo Formation, along the southern margins of the Ordos Basin, were researched based on biomarkers and carbon isotope analyses of outcrop samples to reveal their hydrocarbon potential, organism composition, and depositional environment. Similar to the Yangtze and Tarim blocks, the Lower Cambrian in the southern margin of Ordos Basin, which is a part of North China block, also deposited high abundance marine source rocks. The shales displayed good to excellent total organic carbon (TOC) content (up to 13.75%). The crossplot of phytane/nCis vs. pristane/rtCi7 and organic carbon isotopes indicate the kerogen to be primarily type I-II. The low Hydrogen index values, and high pyrobitumen reflectance (>3.0%) indicate that the Dongpo shales are currently in over-mature stage. The Dongpo shales thus exhibit high hydrocarbon generation potential and might have produced and discharged massive amounts of hydrocarbons during their geological history. The G/C_(30)H ratios (0.17-0.29) and extended tricyclic terpanes Ratio (ETR) values (0.54-0.61) suggest sedimentary environments of stratified water and relatively moderate salinity. In addition, the Dongpo shales display low Pr/Ph (<0.63), low C_(30)~*/C_(29)Ts (<0.44), high C_(35) 22S/C_(34) 22 S (>0.47), and relatively abundant elemental sulfur. These parameters indicate that Dongpo shales were formed in anoxic waters. The abundant steranes and hopanes in the Dongpo shales suggest the diversity of organisms, including eukaryotes and pro-karyotes. The composition of eukaryotes (planktonic algae) is consistent with that of the Yangtze and Tarim blocks, but there are obvious differences with Oman, reflecting the heterogeneity in the global distribution of eukaryotes during the Early Cambrian. In addition, compared with the Yangtze and Tarim, the relatively contribution of prokaryote to Dongpo shale is low, which may also be an important reason for the obvious enriched of ~(13)C in kerogen. The positive relationship between TOC and Pr/Ph and C_(27) St (%) suggests that high primary productivity in the paleoenvironment probably attributed to red algae. The Pr/Ph, C_(35)/C_(34) values and others indexes are related to anoxic conditions, which is good for preserving deposited organic matter.

原文链接:

NSTL