Comparison of Fractured-Horizontal-Well Performance in Tight Sand and Shale Reservoirs

Özkan, Erdal; Brown, Margaret L.; Raghavan, R.; Kazemi, Hossein

doi:10.2118/121290-pa

Cited by 317 publications

(120 citation statements)

References 24 publications

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“…Because of the very low permeability and non-Darcy flow in tight oil reservoirs [5][6][7], a starting pressure gradient exists during waterflooding development, which leads to difficulties during injection, a rapid production decline [8][9][10], and insufficient formation energy challenges [11]. The development of tight oil reservoirs has mainly focused on the combination of horizontal wells and volume fracturing [12][13][14]. A large number of cracks occurs after reservoir volume fracturing [15][16][17][18], and waterflood development often results in a rapid outlet of water from the oil wells [19].…”

Section: Introductionmentioning

confidence: 99%

Waterflooding Huff-n-puff in Tight Oil Cores Using Online Nuclear Magnetic Resonance

et al. 2018

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Given the difficulty in developing waterflooding in tight oil reservoirs, using waterflooding huff-n-puff is an effective method to improve oil recovery. Online nuclear magnetic resonance (NMR) can detect the change in internal oil and water during the core displacement process, and magnetic resonance imaging (MRI) in real time. To improve the tight oil reservoir development effectiveness, cores with different permeability were selected for a waterflooding huff-n-puff experiment. Combined with online NMR equipment, the fluid saturation, recovery rate, and residual oil distribution were studied. The experiments showed that, for tight oil cores, more than 80% of the pores were sub-micro-and micro-nanopores. More than 77.8% of crude oil existed in the sub-micro-and micropores, and movable fluids mainly existed in the micropores with a radius larger than 1 µm. The NMR data and the MRI images both demonstrated that the recovery ratio of waterflooding after waterflooding huff-n-puff was higher than that of conventional waterflooding, and, therefore, residual oil was lower. Choosing two cycles' of waterflooding, huff-n-puff was more suitable for tight oil reservoir development. The production of crude oil increased by 22.2% in the field pilot test, which preliminarily proved that waterflooding huff-n-puff was suitable for tight oil reservoirs.

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Section: Introductionmentioning

confidence: 99%

Waterflooding Huff-n-puff in Tight Oil Cores Using Online Nuclear Magnetic Resonance

et al. 2018

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“…Over the past 30 years, thousands of papers have focused on the transient pressure analysis for a finite-conductivity fracture (Barros-Galvis et al, 2018;Chen et al, 2017;Cinco-Ley and Samaniego, 1981;Ozkan et al, 2011;Tian et al, 2017;Yuan et al, 2015aYuan et al, , 2015b.…”

Section: Introductionmentioning

confidence: 99%

A mathematical model and semi-analytical solution for transient pressure of vertical fracture with varying conductivity in three crossflow rectangular layers

Liu

et al. 2018

Energy Exploration & Exploitation

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This paper first describes a mathematical model of a vertical fracture with constant conductivity in three crossflow rectangular layers. Then, three forms of vertical fracture (linear, logarithmic, and exponential variations) with varying conductivity are introduced to this mathematical model. A novel mathematical model and its semi-analytical solution of a vertical fracture with varying conductivity intercepting a three-separate-layered crossflow reservoir is developed and executed. Results show that the transient pressures are divided into three stages: the linear-flow phase, the medium unsteady-flow stage, and the later pseudo-steady-flow phase. The parameters of the fracture, reservoir, and the multi-permeability medium directly influence the direction, transition, and shape of the transient pressure. Meanwhile, the fracture conductivity is higher near the well bottom and is smaller at the tip of the fracture for the varying conductivity. Therefore, there are many more differences between varying conductivity and constant conductivity. Varying conductivity can correctly reflect the flow characteristics of a vertical fractured well during well-test analysis.

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“…Source-rock matrix permeability is a key parameter to determine gas production rates from source-rock reservoirs (Ozkan et al 2011). Because gas flow in these reservoirs is associated with slip flow, Knudsen diffusion and other mechanisms, the rock matrix permeability, unlike that for conventional rock types, are not an intrinsic rock property, but depend on gas pressure and temperature (Civan 2010;Darabi et al 2012).…”

Section: Introductionmentioning

confidence: 99%

Correction of source-rock permeability measurements owing to slip flow and Knudsen diffusion: a method and its evaluation

2017

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Source-rock permeability is a key parameter that controls the gas production rate from unconventional reservoirs. Measured source-rock permeability in the laboratory, however, is not an intrinsic property of a rock sample, but depends on pore pressure and temperature as a result of the relative importance of slip flow and diffusion in gas flow in lowpermeability media. To estimate the intrinsic permeability which is required to determine effective permeability values for the reservoir conditions, this study presents a simple approach to correct the laboratory permeability measurements based on the theory of gas flow in a micro/nano-tube that includes effects of viscous flow, slip flow and Knudsen diffusion under different pore pressure and temperature conditions. The approach has been verified using published shale laboratory data. The ''corrected'' (or intrinsic) permeability is considerably smaller than the measured permeability. A larger measured permeability generally corresponds to a smaller relative difference between measured and corrected permeability values. A plot based on our approach is presented to describe the relationships between measured and corrected permeability for typical Gas Research Institute permeability test conditions. The developed approach also allows estimating the effective permeability in reservoir conditions from a laboratory permeability measurement.

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Comparison of Fractured-Horizontal-Well Performance in Tight Sand and Shale Reservoirs

Cited by 317 publications

References 24 publications

Waterflooding Huff-n-puff in Tight Oil Cores Using Online Nuclear Magnetic Resonance

Waterflooding Huff-n-puff in Tight Oil Cores Using Online Nuclear Magnetic Resonance

A mathematical model and semi-analytical solution for transient pressure of vertical fracture with varying conductivity in three crossflow rectangular layers

Correction of source-rock permeability measurements owing to slip flow and Knudsen diffusion: a method and its evaluation

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