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Journal of Petroleum Science & Engineering
Elsevier Science B.V.
Journal of Petroleum Science & Engineering

Elsevier Science B.V.

0920-4105

Journal of Petroleum Science & Engineering/Journal Journal of Petroleum Science & Engineering
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    Chaotic dynamics induced by anti-slug control in offshore oil production plants

    Giovani G. GereviniNayher A. ClavijoFabio C. Diehl
    17页
    查看更多>>摘要:The dynamic behavior of an offshore oil production plant obtained through an anti-slug scheme based on a feedback PI control was studied. Three different SISO control scenarios were evaluated considering different controlled variables and the effect of the PI control constants tuning on the suppression of oscillatory behavior related to the slugging flow phenomenon. It was shown that the PI control, when the pressure at the top of the riser was the controlled variable, was able to induce chaotic oscillations. Additionally, the proper characterization of the chaotic behavior was performed allowing to determine the PI control tuning conditions that favor the appearance of this complex behavior.
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    • NSTL

    Vibration-assisted annular fluid displacement for rig-less well abandonment operations

    Hans Joakim SkadsemKnut Erik Teigen GiljarhusFiona Oijordsbakken Fredheim
    13页
    查看更多>>摘要:Through-tubing abandonment is the operation where the production tubing is cut or punched and cemented inside the production casing. This can establish a full cross-sectional barrier or isolation in wells where the cement behind the production casing provides zonal isolation. Furthermore, isolation in the form of a through-tubing abandonment plug can be placed from a light-well intervention vessel, which reduces the risk and carbon footprint compared to conventional abandonment designs that rely on a full mobile offshore drilling unit. A potential challenge involved in placing the through-tubing abandonment plug is the risk of incomplete fluid displacement from the annulus behind the tubing: The tubing eccentricity may be considerable where the barrier should be placed, and the original packer fluid may be contaminated resulting in unfavorable displacement conditions. Furthermore, the tubing cannot be reciprocated or rotated to compensate for these conditions. Agitator tools that generate lateral and axial vibrations in the tubing for mitigating potentially adverse displacement conditions have recently become available to the industry. We study potential effects of such tools by performing annular displacement experiments using a novel test rig that enables lateral movement of the inner tubing. The original fluid to be displaced was viscosified with a polymer additive to generate apparent yield stress behavior and to thereby develop challenging displacement conditions, particularly in the eccentric annulus. Experimental results and supporting numerical simulations show that lateral motion of the tubing is effective in displacing the yield stress fluid from the narrow side of the eccentric annulus, and to oppose the tendency toward stratification in both concentric and eccentric annuli. The experiments further show that vibration is effective in improving the displacements at inclinations ranging from vertical to 80° from the vertical, and that high frequency vibrations are more effective than lower frequency vibrations at the same amplitude. Results from a mechanical vibration analysis suggests the vibration amplitudes increase with increasing flow rates, and that potentially beneficial vibrations can propagate over axial lengths that are comparable or longer than minimum barrier length requirements.
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    • NSTL

    Enhancing N2 and CO2 foam stability by surfactants and nanoparticles at temperature and various salinities

    Ayomikun BelloAnastasia IvanovaAlexey Cheremisin
    16页
    查看更多>>摘要:To keep up with the ever-growing global energy demand, the petroleum industry has shifted its attention to enhanced oil recovery (EOR) methods, which ensure 30%-60% of residual oil recovery following primary and secondary recovery processes. Foam injection is one of these methods. Due to their low sensitivity to gravity and permeability heterogeneities which improve sweep efficiency, foams are preferable injection fluids than water or gas. However, this recovery technique is not widely used due to the thermodynamic instability of foams. This work aims to take advantage of recent breakthroughs in nanoparticles engineering to build long-lasting nanoparticle-stabilized foams, as nanoparticles can withstand high temperatures and reservoir conditions for a prolonged time. Therefore, to achieve this goal, a comprehensive set of screening experiments was conducted, which included an investigation of the influence of ionic surfactants on foam stability with and without silica nanoparticles at room and elevated temperatures, as well as bulk foam tests with air, nitrogen, and CO2, characterization of foaming suspensions, and analysis of foam texture and morphology. The half-life duration, foam quality, and foam composite index were used to determine the stability of the generated foams. The findings demonstrated that the addition of 0.05% silica nanoparticles could improve the half-life of nitrogen and CO2 foam up to 13% and 40%, respectively. However, the extent of this depends on temperature, salinity and optimal concentration of nanoparticles. Furthermore, the results showed that optimal concentrations of nanoparticles and surfactants should be carefully determined in order to achieve a positive synergistic effect. Results illustrated that selected nanoparticles-surfactant formulations appear very promising for EOR as they show high stability at elevated temperatures and tolerance to different mineralization.
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    A novel approach for wettability estimation in geological systems by fluid-solid interfacial area measurement using tracers

    Deepshikha SinghShantanu RoyHarish Jagat Pant
    12页
    查看更多>>摘要:Wettability plays a vital role in many applications of flow in porous media and affects Darcy scale flow parameters by influencing the fluid-solid interfacial area. Therefore, quantifying the fluid-solid interfacial area can provide a way to measure wettability at the Darcy scale. Here, we experimentally explore a dual-tracer method, which can also be scaled to large geological reservoirs to quantify the fluid-solid interfacial area during the multiphase flow through a porous medium for different wetting conditions. Using our experiments, we demonstrate the influence of different saturations, wettability and flow conditions on the solid-liquid interfacial area. When oil is in the residual phase, we observe that the solid-water interfacial area increases with the increase in water saturation for the water-wet and mixed-wet cases. However, the water-solid interfacial area decreases with an increase in water saturation for the oil-wet case. We increase the water saturation by increasing the water flow rate; therefore, the anomalous behaviour seen in the oil-wet case can be attributed to the rearrangement of oil and water at higher water flow rates. When both oil and water are flowing, the solid-water interfacial area increases with water saturation for all the wettability cases and increases in water wettability as anticipated. Synopsis: Wettability measurements at Darcy-scale give a broad idea of overall subsurface wetting conditions for application in C02 sequestration, ground-water remediation or oil recovery.
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    • NSTL

    Numerical investigation of the fracture network morphology in multi-cluster hydraulic fracturing of horizontal wells: A DDM-FVM study

    Chang-Xin YangLiang-Ping YiZhao-Zhong Yang
    21页
    查看更多>>摘要:Hydraulic fracturing is the most effective method to enhance the recovery of unconventional oil and gas via the formation of complex connected fracture networks. In this study, a pseudo three-dimensional fully fluid-solid coupled model is established to investigate the interaction between hydraulic fractures (HFs) and natural fractures (NFs), and the fracture network propagation process. The displacement discontinuity method (DDM) and finite volume method (FVM) are applied to simulate the rock deformation of the reservoir and fracturing fluid flow into the fracture networks, respectively. The influence of the stress shadow, flow rate distribution, comprehensive fluid loss, and complex extension behavior are considered in this model. A modified analytical crossing criterion is used to predict the interaction between the HF and NF. To improve the accuracy of the pressure calculation, the width of the fracture vertical cross-section is replaced by an equivalent width. The coupled equations are solved by Newton-Raphson iteration method. The numerical results of the proposed model agreed well with published analytical and experimental results. Based on the model, detailed sensitivity analyses are conducted to investigate the interaction between HFs and NFs, and the geometries of the fracture networks. The simulation results show that the fracture network morphology is significantly affected by NFs in naturally fractured reservoirs. The stress interference between HFs can weaken the effect of the horizontal stress difference; thus, NFs can be activated effectively. In addition, the complexity of the fracture network is proportional to the activation rate of the NFs. A more complex fracture network can be formed under the following conditions: a small horizontal stress difference, large NF length, low injection rate and low viscosity. It is noteworthy that a smaller value is not always better for cluster spacing. An optimal cluster spacing exist to obtain good results for reservoir stimulation.
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    • NSTL

    A new multi-fracture geometry inversion model based on hydraulic-fracture treatment pressure falloff data

    Zhiyong TuXiaodong HuFujian Zhou
    13页
    查看更多>>摘要:Multi-fracture hydraulic fracturing has been widely used in unconventional oil or gas production. Determining the fracture geometry at the end of multi-fracture propagating simultaneously and early estimating of the stimulation performance can improve the understanding of the well productivity. Coupled with other information on treatment execution, this understanding may help define changes in treatment design and execution that increase well productivity. G-function pressure drop curves analysis is an important method to determine the single fracture geometry. However, it is difficult to estimate the multi-fracture geometry in each fracturing stage by G-function model. In this paper, we propose a new model to calculate the multi-fracture geometry based on the G-function plot of pressure falloff data after hydraulic-fracture treatment in each fracturing stage. First, stress shadow and the dynamic partitioning of flow rate are first considered in the G-function model for the calculation of multi-fracture geometry distribution. Second, proportional function of fracture length is incorporated in the G-function model in this paper, which solves the problem of the non-uniqueness of fracture lengths and widths calculation outcomes. Through comparing with the numerical simulation results, our model is verified. Finally, a sensitivity analysis of the fracture control parameters is performed based on our model. This paper provides a new semi-analytical method to quickly determine the multi-fracture geometry after each horizontal well fracturing stage. It can be used to evaluate the performance of multi-fracture hydraulic fracturing and help improve the well productivity.
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    • NSTL

    Effects of hydrostatic pressure on hydraulic fracturing properties of shale using X-ray computed tomography and acoustic emission

    Hang ZhaoBing LiangWeiji Sun
    13页
    查看更多>>摘要:The study of the hydraulic fracturing characteristics in shale reservoirs is crucial for improving the permeability of shale gas reservoirs. In this study, hydraulic fracturing tests are conducted on full-diameter shale cores, and the hydraulic fracturing characteristics of shale with different bedding angles under high hydrostatic pressure are studied. The results show that under a hydrostatic pressure of 59 MPa, the shale sample will rupture twice in the breakdown stage during hydraulic fracturing. When the bedding inclination increases from 0° to 90°, the shale fracture breakdown pressure first decreases and then increases, showing an overall downward trend. Under high hydrostatic pressure, shale specimen surface fracture morphology and X-ray computed tomography reveal that a bedding angle close to 45° is more conducive to forming a complex hydraulic fracture network, which makes the fractal dimension of the fracture network larger. The bedding plane of shale is the direct cause of the diverse propagation patterns of hydraulic fractures. The b-value is a parameter that characterizes the magnitude-frequency relationship of an earthquake, and it is closely related to the rock rupture process. The b-value varies with different trends with the expansion of hydraulic fractures, but they all reach the lowest point before the failure of the shale sample. The higher the hydraulic fracture network complexity, the lower the peak b-value is. This work provides a qualitative understanding and scientific explanation of the hydraulic fracturing characteristics of anisotropic shale under hydrostatic pressure.
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    • NSTL

    Additive and alternative materials to cement for well plugging and abandonment: A state-of-the-art review

    Farhad AslaniYifan ZhangDavid Manning
    20页
    查看更多>>摘要:Data from Rystad Energy shows that, till 2020, the US Gulf of Mexico, the largest oil and gas production field, has a total of 34.4 thousand drilled wells with only 44% have been plugged and abandoned and 19.2 thousand wells are pending to be plugged in the future. Thereinto, 71% of the inventory is more than 40 years old. The US Environmental Protection Agency reported that in 2019, the annual CH4 emission from these unplugged wells reached 209 Mt and the leakage of fluids could destroy the environment and threaten human health eventually. After the implementation of idle iron policy which requires titleholders to decommission the abandoned wells within specific periods, more wells are urgently to be plugged and abandoned. Cement or cementitious materials as the commonly used materials for well decommissioning serving as physical plugs, always suffer shrinkage, poor resistance to corrosive environment, instability under harsh environments, etc., which will initiate or accelerate fluid leakage. Furthermore, since the well conditions vary largely, the requirements or benchmarks of plugging materials may be completely different, this paper therefore aims to summarise and update the findings of past research and review papers, and list the regulations for well cementing as well as commonly used detection methods, identify available additives of ordinary cement that can modify the mechanical, physical, and chemical properties of cement plugs under specific well conditions, enumerate the potential alternative materials that can replace cement plugs, and eventually help the academia or industry to be familiar with relevant regulations or standards, material requirements, and associated detection technologies, recognise the available possibilities and determine the preferred ones easily. Findings of this paper indicate additives such as pozzolans, fibres, self-healing additives, and nanoparticles can significantly improve the mechanical properties, physical properties, chemical inertness, and durability. Alternatives including bentonite, bismuth, modified in-situ material, geopolymers, resin, and slags also exhibit adequate performance as cement replacement but require more field attempts to further assess their feasibilities.
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    • NSTL

    Geochemistry and depositional environment of the Mesoproterozoic Xiamaling shales, northern North China

    Jin WuHao LiFariborz Goodarzi
    15页
    查看更多>>摘要:The Mesoproterozoic Xiamaling shales from Xiahuayuan area, southeastern Xuanlong sag, Northern China, were examined the elemental analysis by applying the inductively coupled plasma-mass spectrometry (ICP-MS). The Xiamaling shales have good to excellent oil hydrocarbon generation potential with type II kerogenas demonstrated by high content of alginate macerals, TOC, HI, S1 + S2 and extractable organic matter (EOM). The Xiamaling shales were deposited under a marine environment according to boron (B) (56-111 ppm) and other trace elements concentration, which is consistent with the geological settings. These shales can be classified into three types: (1) Type I is a coastal fades, which is influenced by fresh riverine water and has low B content of 56-61 ppm; (2) Type II is a marginal marine with B content of 73-79 ppm; and (3) type III has high B content of 111 ppm, typical of a brackish, and open marine environment. The Xiamaling shales have high B (>50 ppm), low Na, Ca, Ce, Mn, and rare earth elements (REEs). According to the elemental composition and ratios, the Xiamaling sediments were derived from the felsic source, which has suffered from moderate to strong chemical weathering based on the CIA, ICV, and PIA values. The Xiamaling marine shales were mostly deposited under dysoxic-anoxic conditions. The paleoclimate during the deposition of the Xiamaling shales was warm and humid based on the cross plots of Sr/Ca vs Mn/Ca values and Sr/Cu vs Rb/Sr ratios. Their total REE (ZREE) contents increase from coastal towards the open marine zone. The Xiamaling shales display a negative Ce anomaly, representative of marine shale, and show a negative Eu anomaly, whidi is representative of lacustrine oil shale and the Post-Archean Australian Shale (PAAS) and is different from typical marine shale of younger age, indicating the influx of terrestrial sediment.
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    • NSTL

    Experimental evidence of chemical osmosis-driven improved oil recovery low-salinity water flooding: Generation of osmotic pressure via oil-saturated sandstone

    Mikio TakedaMitsuo ManakaDaisuke Ito
    10页
    查看更多>>摘要:Chemical osmosis caused by semipermeability and salinity gradient of reservoir rock has been considered to improve oil recovery obtained by low-salinity water flooding. However, the generation of osmotic pressure by rocks containing crude oil has not been reported. In this study, an oil-saturated sandstone generated osmotic pressures of up to 37 kPa at a salinity difference of 0.6-0.1 M NaCl and expelled crude oil from the surface facing low-salinity water (LSW). The results demonstrate that chemical osmosis can drive directional oil migration toward LSW on the scale of rock. The tested sandstone exhibited a clay content of 17 wt%; however, the oil-free core did not generate osmotic pressure. In contrast, the oil-saturated core generated osmotic pressures at the high-salinity water (HSW) facing its surface five days after being exposed to the salinity difference. The delayed pressure generation can be attributed both to the water intrusion into potential membranes (i.e., clay minerals, crude oil, and the interface between oil and minerals) and to the evolution of salinity gradient in the core. In the last experiment, on the same core using a salinity difference of 0.9-0.1 M NaCl, osmotic pressure developed immediately because both the active membranes and saline water already existed across the core. These results suggest that the potential semipermeability of reservoir rocks containing crude oil and saline water can promptly cause chemical osmosis upon exposure to the change in salinity difference. Although the cumulative flux driven by the osmotic pressure likely exceeded the volume of injected crude oil, chemical osmosis continued generating osmotic pressure until the end of the experiments. These contradictory results suggest that the chemical osmosis-driven directional oil migration toward the LSW occurs preferentially through conductive large-sized pores, and the residual oil in small-sized pores and clay minerals exert long-lasting semipermeability to cause chemical osmosis further toward the HSW.
      原文链接:
    • NSTL