Effects of rock pore sizes on the PVT properties of oil and gas-condensates in shale and tight reservoirs

Arash Kamari; Lei Li; James J. Sheng

doi:10.1016/j.petlm.2017.06.002

Petroleum ›› 2018, Vol. 4 ›› Issue (2) :148 -157. DOI: 10.1016/j.petlm.2017.06.002

research-article

Effects of rock pore sizes on the PVT properties of oil and gas-condensates in shale and tight reservoirs

Author information +

History +

PDF

Abstract

Shales make up a large proportion of the rocks with extremely low permeability representing many challenges which can be complex in many cases. A careful study of rock and fluid properties (i.e. PVT of shales) of such resources is needed for long-term success, determining reservoirs quality, and increased recovery factor in unique unconventional plays. In this communication, a comprehensive thermodynamic modelling is undertaken in which capillary pressure is coupled with the phase equilibrium equations. To this end, the data associated with both shale oil and gas-condensates of Eagle Ford shale reservoir located in South Texas, U.S., is used. Different properties, including bubble and dew point pressures, capillary pressure, interfacial tension, liquid and gas densities, and liquid and gas viscosities, are predicted observing the effects of rock pore sizes by the thermodynamic modelling performed in this study. The results demonstrate that the thermodynamic model developed in this study is capable of simulating the PVT properties of oil and gas-condensates in shale and tight reservoirs. For a binary mixture 25:75 C₁/C₆, the bubble point pressure at different reservoir temperature is increased by increasing the pore sizes from 10 to 50 nm. Furthermore, an increase in pore sizes from 10 to 50 nm can increase the dew point pressure for a studied binary mixture 75:25 C₁/C₆.

Keywords

Shale / Pore size / Oil / Gas-condensate / Thermodynamic modelling

Cite this article

Download citation ▾

Arash Kamari, Lei Li, James J. Sheng. Effects of rock pore sizes on the PVT properties of oil and gas-condensates in shale and tight reservoirs. Petroleum, 2018, 4(2): 148-157 DOI:10.1016/j.petlm.2017.06.002

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	C. Chen, Multiscale imaging, modeling, and principal component analysis of gas transport in shale reservoirs, Fuel 182 (2016) 761-770.

[2]	N.S. Alharthy, T. Nguyen, H. Kazemi, T. Teklu, R. Graves,Multiphase compositional modeling in small-scale pores of unconventional shale reservoirs, in:SPE 166306 Presented in SPE Annual Technical Conference and Exhibition Held in New Orleans, Louisiana, 30 Septembere2 October, 2013.

[3]	J.H. Chen, A. Mehmani, B. Li, D. Georgi, G. Jin,Estimation of total hydrocarbon in the presence of capillary condensation for unconventional shale reservoirs, in:SPE 164468 Presented in SPE Middle East Oil and Gas Show and Conference Held in Manama, Bahrain, 10e13 March, 2013.

[4]	L. Du, L. Chu,Understanding anomalous phase behavior in unconventional oil reservoirs, in:SPE 161830 Presented in SPE Canadian Unconventional Resources Conference Held in Calgary, Alberta, Canada, 30 Octobere1 November, 2012.

[5]	L. Jin, Y. Ma, A. Jamili,Investigating the effect of pore proximity on phase behavior and fluid properties in shale formations, in:SPE 166192 Presented in SPE Annual Technical Conference and Exhibition Held in New Orleans, Louisiana, 30 Septembere2 October, 2013.

[6]	Y. Ma, L. Jin, A. Jamili,Modifying van der Waals equation of state to consider influence of confinement on phase behavior, in:SPE 166476 Presented in SPE Annual Technical Conference and Exhibition Held in New Orleans, Louisiana, 30 Septembere2 October, 2013.

[7]	B. Nojabaei, R.T. Johns, L. Chu,Effect of capillary pressure on phase behavior in tight rocks and shales, in:Paper SPE 159258 Presented at the SPE Annual Technical Conference and Exhibition Held in San Antonio, Texas, 31 Octobere1 November, 2012.

[8]	P. Sigmund, P. Dranchuk, N. Morrow, R. Purvis, Retrograde condensation in porous media, Soc. Pet. Eng. J. 13 (1973) 93-104.

[9]	A. Brusilovsky, Mathematical simulation of phase behavior of natural multicomponent systems at high pressures with an equation of state, SPE Reserv. Eng. 7 (1992) 117-122.

[10]	Z. Qi, S. Wang, Z. Du, B. Liang, R. Deng, W. Zhao, A new approach for phase behavior and well productivity studies in the deep gas-condensate reservoir with low permeability, in: Production and Operations Symposium, Society of Petroleum Engineers, 2007.

[11]	Y. Wang, B. Yan, J. Killough,Compositional modeling of tight oil using dynamic nanopore properties, in:SPE 166267 Presented in SPE Annual Technical Conference and Exhibition Held in New Orleans, Louisiana, USA, 30 Septembere2 October, 2013.

[12]	Y. Zhang, H.R. Lashgari, Y. Di, K. Sepehrnoori, Capillary pressure effect on phase behavior of CO2/hydrocarbons in unconventional reservoirs, Fuel 197 (2017) 575-582.

[13]	B. Nojabaei, R.T. Johns, L. Chu, Effect of capillary pressure on phase behavior in tight rocks and shales, SPE Reserv. Eval. Eng. 16 (2013) 281-289.

[14]	Y. Tian, W. Ayers, P. McCain, Regional impacts of lithologic cyclicity and reservoir and fluid properties on Eagle Ford shale well performance, in: SPE Unconventional Resources Conference, Society of Petroleum Engineers, 2014.

[15]	U. EIA,ReviewofEmergingResources:USShaleGas and ShaleOil Plays vol. 135, Government. US Energy Information Administration, 2011. http://205.254.

[16]	A.A. Inamdar, T.M. Ogundare, R. Malpani, W.K. Atwood, K. Brook, A.M. Erwemi, D. Purcell, Evaluation of stimulation techniques using microseismic mapping in the Eagle Ford Shale, in: Tight Gas Completions Conference, Society of Petroleum Engineers, 2010.

[17]	N.A. Stegent, A.L. Wagner, J. Mullen, R.E. Borstmayer, Engineering a successful fracture-stimulation treatment in the Eagle Ford shale, in: Tight Gas Completions Conference, Society of Petroleum Engineers, 2010.

[18]	J. Mullen, Petrophysical characterization of the Eagle Ford shale in South Texas, in: Canadian Unconventional Resources and International Petroleum Conference, Society of Petroleum Engineers, 2010.

[19]	A. Orangi, N.R. Nagarajan, M.M. Honarpour, J.J. Rosenzweig, Unconventional shale oil and gas-condensate reservoir production, impact of rock, fluid, and hydraulic fractures, in: SPE Hydraulic Fracturing Technology Conference, Society of Petroleum Engineers, 2011.

[20]	J.M. Prausnitz, R.N. Lichtenthaler, E.G. de Azevedo, Molecular Thermodynamics of Fluid-phase Equilibria, Pearson Education, 1998.

[21]	J. Gmehling, B. Kolbe, M. Kleiber, J. Rarey, Chemical Thermodynamics for Process Simulation, John Wiley & Sons, 2012.

[22]	T. Ahmed, Equations of State and PVT Analysis, Elsevier, 2013.

[23]	G.M. Wilson, A modified Redlich-Kwong equation of state, application to general physical data calculations,in:65th National AIChE Meeting, Cleveland, OH, 1969.

[24]	B.A. Haider, in: Impact of Capillary Pressure and Critical Properties Shift Due to Confinement on Hydrocarbon Production from Shale Reservoirs, Stanford University, 2015.

[25]	H. Rachford Jr., J. Rice, Procedure for use of electronic digital computers in calculating flash vaporization hydrocarbon equilibrium, J. Pet. Technol. 4 (1952), 19-13.

[26]	W.D. McCain, The Properties of Petroleum Fluids, PennWell Books, 1990.

[27]	Y. Xiong, P. Winterfeld, C. Wang, Z. Huang, Y.-S. Wu, Effect of large capillary pressure on fluid flow and transport in stress-sensitive tight oil reservoirs, in: SPE Annual Technical Conference and Exhibition, Society of Petroleum Engineers, 2015.

[28]	A.L. Lee, M.H. Gonzalez, B.E. Eakin, The viscosity of natural gases, J. Pet. Technol. 18 (1966), 997-991,000.

[29]	J. Lohrenz, B.G. Bray, C.R. Clark, Calculating viscosities of reservoir fluids from their compositions, J. Pet. Technol. 16 (1) (1964), 171-171,176.