The vaporization of a liquid front moving through a hot porous rock

Woods, Andrew W.; Fitzgerald, Shaun

doi:10.1017/s0022112093003520

Cited by 45 publications

(37 citation statements)

References 7 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As a result, the interfacial temperature Ti is also lower, and so, the amount of energy released by the hot rock as it is invaded by the liquid and cools to temperature Ti is greater. As a result, there is more energy available for vaporization [Woods and Fitzgerald, 1993].…”

Section: This Has a Linearized Formmentioning

confidence: 99%

Instabilities during liquid migration into superheated geothermal reservoirs

Fitzgerald¹,

Woods²

1998

Water Resources Research

Self Cite

View full text Add to dashboard Cite

Abstract. We examine the stability of a vaporizing liquid front migrating through a permeable rock. We show that such liquid-vapor fronts may become unstable if a sufficient fraction of the liquid vaporizes. This instability is a result of the different speed of the fluid on each side of the front. We also identify that short-wavelength perturbations are stabilized by thermal conduction, while long-wavelength perturbations are stabilized as a result of the compressibility of the vapor. Furthermore, under conditions typical of geothermal reservoirs, where the pressure is -10 atm and the temperature is -200ø-300øC, we find that if the permeability of the system is smaller than •10 -•s m 2, then these two stabilizing mechanisms overlap and the system becomes stable to perturbations of any wavelength. We also examine the role of gravity in suppressing the instability of an ascending front and promoting the instability of a descending front. We apply our results to the vapor-dominated geothermal reservoirs at Larderello, Italy, and the Geysers, California, to predict conditions under which liquid fronts, advancing into superheated vapor, are stable.

show abstract

Section: This Has a Linearized Formmentioning

confidence: 99%

Instabilities during liquid migration into superheated geothermal reservoirs

Fitzgerald¹,

Woods²

1998

Water Resources Research

Self Cite

View full text Add to dashboard Cite

show abstract

“…Vapour extraction from a water-saturated porous reservoir (Woods & Fitzgerald 1993;Tsypkin & Woods 2004), condensing flow of steam (Bergins, Crone & Strauss 2005), motion of aqueous saline solution through a low-permeability fracture (Tsypkin & Woods 2005), gas extraction from multilayered rocks (Farcas & Woods 2007) represent examples of geothermal applications of phase change in porous media.…”

Section: Introductionmentioning

confidence: 99%

Asymptotic analysis of a Hiemenz flow in a low-porosity medium with phase change

Kokubun

Fachini

2012

J. Fluid Mech.

View full text Add to dashboard Cite

In the present work, the features of liquid evaporation inside a low-porosity medium subjected to an impinging stream of hot gas is investigated analytically. The flow is analysed for a non-Darcy model, in which viscous and convective terms are considered in the Darcy pressure equation. A low-volatility liquid is considered, so that a low-vaporization regime is established. The rates of heat transfer between gas and solid and between liquid and solid are assumed to be high. Owing to differences between phase properties, in the system under study, different physical processes occur at different length scales. Using asymptotic expansions, expressions for the three phases that occur in this problem are obtained, in each of their length scales. The results predict that high injection temperatures are needed for phase change to occur, as a result of the low volatility of the liquid. Likewise, the enhancement of the vaporization rate due to heat conduction in the porous medium is quantified. The Hiemenz flow pressure term is modified to incorporate the effect of the porous medium, which is necessary for a solution to be found.

show abstract

“…The problems associated with water injection into geothermal reservoirs were investigated by a number of authors using analytical and numerical methods [1][2][3][4][5][6][7][8]. Bodvarsson [1] found a solution of the traveling wave type for a flow with spherical symmetry, which enables one to estimate the volume of water injected into a geothermal reservoir.…”

Section: Introductionmentioning

confidence: 99%

“…The exactness of analytical solution was confirmed by results of numerical solutions. Woods and Fitzgerald [5][6][7] treated the radial problem on liquid motion in superheated fissured rocks and derived simple solutions and estimates providing an asymptotic description for two limiting cases at high and low rates of injection. Barmin and Tsypkin [8] derived a complete system of boundary conditions in the boiling front, which includes the laws of conservation for mass and energy and the Clausius-Clapeyron relation, and gave the solution to one-dimensional problem in a linear approximation for injection to low-permeability rocks.…”

Section: Introductionmentioning

confidence: 99%

Mathematical modeling of cold water injection into a depleted high-temperature geothermal reservoir

2006

View full text Add to dashboard Cite

The injection of cold water into a geothermal reservoir containing superheated vapor is investigated in a one-dimensional approximation. Simplifying assumptions are used for a highly permeable porous medium to derive a self-similar solution and asymptotic estimates for the velocity of boiling front and for the temperature of phase transition. It is demonstrated that the results obtained using a simplified model agree well with the results of numerical simulation using the TOUGH2 computer codes.

show abstract

The vaporization of a liquid front moving through a hot porous rock

Cited by 45 publications

References 7 publications

Instabilities during liquid migration into superheated geothermal reservoirs

Instabilities during liquid migration into superheated geothermal reservoirs

Asymptotic analysis of a Hiemenz flow in a low-porosity medium with phase change

Mathematical modeling of cold water injection into a depleted high-temperature geothermal reservoir

Contact Info

Product

Resources

About