The Effect of the Absorbed Fluid Layer on Flow in a Capillary Tube

Li, Y.; Ye, Jun; Yang, Yongfei

doi:10.1080/10916466.2011.594828

Cited by 8 publications

(3 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…1393-1396pore-throat but also changes the viscosity of fluid. An empirical equation for the thickness of boundary fluid layer was used in this paper[5…”

mentioning

confidence: 99%

Boundary effect on liquid invasion in tight gas reservoirs

Ren

Meng

et al. 2015

THERM SCI

View full text Add to dashboard Cite

Liquid invasion is an important transport phenomenon in many geophysical and environmental applications. A new capillary model considering boundary effect is proposed to reveal its mechanism. The boundary fluid layer not only reduces the effective flow radius, but also changes the viscosity of fluid. Thus the capillary force and viscosity resistance increases, however, the increase of capillary force is faster than that of viscosity resistance, therefore the invasion front arrives at the critical distance earlier.

show abstract

“…1393-1396pore-throat but also changes the viscosity of fluid. An empirical equation for the thickness of boundary fluid layer was used in this paper[5…”

mentioning

confidence: 99%

Boundary effect on liquid invasion in tight gas reservoirs

Ren

Meng

et al. 2015

THERM SCI

View full text Add to dashboard Cite

show abstract

“…In this process, water will be imbibed into matrix in the fractured reservoir by many influences, including capillary pressure [3][4][5], chemical osmotic pressure [6], pore network [7][8][9], and clay mineral [10], which is called spontaneous imbibition. Also, leakage, lost circulation, and induced fracture in drilling process will lead to fracturing fluid being pumped into formation [11][12][13], which will also cause imbibition process and may change the stress field near wellbore [14] and drilling state [15,16].…”

Section: Introductionmentioning

confidence: 99%

Mathematical Model for the Fluid-Gas Spontaneous Displacement in Nanoscale Porous Media considering the Slippage and Temperature

Liu

Lin

Cao

et al. 2018

Mathematical Problems in Engineering

View full text Add to dashboard Cite

The fracturing fluid-gas spontaneous displacement during the fracturing process is important to investigate the shale gas production and formation damage. Temperature and slippage are the major mechanisms underlying fluid transport in the micro-/nanomatrix in shale, as reported in the previous studies. We built a fracturing fluid-gas spontaneous displacement model for the porous media with micro-/nanopores, considering two major mechanisms. Then, our spontaneous displacement model was verified by the experimental result of the typical shale samples and fracturing fluids. Finally, the influences of temperature, slip length, and pore size distribution on the spontaneous imbibition process were discussed. Slippage and temperature significantly influenced the imbibition process. Lower viscosity, higher temperature, and longer slip length increased the imbibition speed. Ignoring the temperature change and slippage will lead to significant underestimation of the imbibition process.

show abstract

“…Among of them, several permeability models coupling boundary-layer effect were proposed, and most of them were based on the capillary tube model. 8,9 Experiments also were conducted to measure the thickness of boundarylayers and investigate the effect of boundary-layer on effective liquid permeability. 6,[11][12][13][14][15][16] The experiment results showed that the thickness of boundarylayer is related to pressure gradient, fluid viscosity, pore radius and fluid type.…”

Section: Introductionmentioning

confidence: 99%

A Fractal Permeability Model Coupling Boundary-Layer Effect for Tight Oil Reservoirs

et al. 2017

View full text Add to dashboard Cite

A fractal permeability model coupling non-flowing boundary-layer effect for tight oil reservoirs was proposed. Firstly, pore structures of tight formations were characterized with fractal theory. Then, with the empirical equation of boundary-layer thickness, Hagen-Poiseuille equation and fractal theory, a fractal torturous capillary tube model coupled with boundary-layer effect was developed, and verified with experimental data. Finally, the parameters influencing effective liquid permeability were quantitatively investigated. The research results show that effective liquid permeability of tight formations is not only decided by pore structures, but also affected by boundary-layer distributions, and effective liquid permeability is the function of fluid type, fluid viscosity, pressure gradient, fractal dimension, tortuosity fractal dimension, minimum pore radius and maximum pore radius. For the tight formations dominated with nanoscale pores, boundary-layer effect can significantly reduce effective liquid permeability, especially under low pressure gradient.

show abstract

The Effect of the Absorbed Fluid Layer on Flow in a Capillary Tube

Cited by 8 publications

References 10 publications

Boundary effect on liquid invasion in tight gas reservoirs

Boundary effect on liquid invasion in tight gas reservoirs

Mathematical Model for the Fluid-Gas Spontaneous Displacement in Nanoscale Porous Media considering the Slippage and Temperature

A Fractal Permeability Model Coupling Boundary-Layer Effect for Tight Oil Reservoirs

Contact Info

Product

Resources

About