Low permeability reservoirs account for an increasing proportion of oil production. Threshold pressure gradient is an important factor that governs the flow in low permeability porous media. The 1-D seepage governing equation (SGE) for low permeability porous media can be derived from the 1-D core flooding experimental rule. In the literature, for isotropic porous media, the SGE with a threshold pressure gradient (TPG) in Cartesian and cylinder coordinate systems are incompatible to each other. In addition, irrational results were found in simulation using SGEs in the Cartesian coordinate system. In this study, 3-D SGEs with a TPG in the Cartesian coordinate system and for radial flow in the cylindrical coordinate system are derived from the vector form of the seepage velocity in 3-D domain which is transformed from the 1-D seepage velocity vector. The 1-D equation degenerated from the 3-D SGE of low permeability media is in accordance with the 1-D SGE. The derived SGE of low permeability porous media in Cartesian coordinate systems is consistent with that in cylindrical coordinate systems. So, the contradiction of SGEs with a TPG in literature is resolved. For anisotropic reservoirs with a TPG, with the assumption that the impeding of a TPG to flow in porous media occurs in the opposite direction of the seepage velocity vector, the general seepage initiation condition for anisotropic porous media with a TPG is derived. The SGEs for anisotropic porous media with a TPG under a specific condition in Cartesian coordinate systems and for radial flow in cylindrical coordination the systems are derived, and then are degenerated to isotropic cases. It is found that a simple form of the SGE in anisotropic porous media with a TPG can only be derived when the flow is radial. So, it is suggested that numerical simulations for anisotropic porous media with a TPG should use the equation set composed by the pressure and seepage velocity vector. The analysis also indicates that a TPG of anisotropic reservoirs is a two-order tensor, and cannot be represented by a vector. However, the current form of effective pressure gradient requires further investigation.

Cited as: Han, G., Liu, Y., Nawnit, K., Zhou, Y. Discussion on seepage governing equations for low permeability reservoirs with a threshold pressure gradient. Advances in Geo-Energy Research, 2018, 2(3): 245-259, doi: 10.26804/ager.2018.03.03

Chen, Y. Improper use of the starting pressure gradient of linear flow in the plane radial flow equation. Acta Petrolei Sinica 2011, 32(6): 1088-1092. (in Chinese)

Civan, F. Modeling gas flow through hydraulically-fractured shale-gas reservoirs involving molecular-to-inertial trans-port regimes and threshold-pressure gradient. Paper SPE 166324 Presented at SPE Annual Technical Conference and Exhibition, New Orleans, Louisiana, USA, 30 September-2 October, 2013.

Civan, F. Effect of poroelasticity, pore confinement, molecular-to-inertial transport, and threshold pressure on flow of gas through hydraulically-fractured shale-gas reservoirs. Paper SPE 187056 Presented at SPE Annual Technical Conference and Exhibition, San Antonio, Texas, USA, 9-11 October, 2017.

Ding, J., Yang, S., Nie, X., et al. Dynamic threshold pressure gradient in tight gas reservoir. J. Nat. Gas Sci. Eng. 2014, 20(2): 155-160.

Diwu, P., Liu, T., You, Z., et al. Effect of low velocity non-Darcy flow on pressure response in shale and tight oil reservoirs. Fuel 2018, 216: 398-406.

Dou, H., Ma, S., Zou, C., et al. Threshold pressure gradient of fluid flow through multi-porous media in low and extra-low permeability reservoirs. Sci. China Earth Sci. 2014, 57(11): 2808-2818.

Dudgeon, C.R. An experimental study of the flow of water through coarse granular media. La Houille Blanche 2010, 21(7): 785-801.

Escobar, F.H., Zhao, Y.L., Pournik, M., et al. Interpretation of pressure tests in uniform-flux fractured vertical wells with threshold pressure gradient in low permeability reservoirs. ARPN J. Eng. Appl. Sci. 2015, 10(20): 9364-9372.

Guo, J., Zhang, S., Zhang, L., et al. Well testing analysis for horizontal well with consideration of threshold pressure gradient in tight gas reservoirs. J. Hydrodyn. 2012, 24(4): 561-568.

Huang, K., Xue, M., Lu, M. Tensor Analysis. Beijing, Tsinghua University Press, 2003. (in Chinese)

Kong, X. Advanced Mechanics of Flow in Porous Media (2ed). Hefei, Press of University of Science and Technology of China, 2010. (in Chinese)

Li, D., Zha, W., Liu, S., et al. Pressure transient analysis of low permeability reservoir with pseudo threshold pressure gradient. J. Pet. Sci. Eng. 2016, 147: 308-316.

Li, S., Cheng, L., Li, X., et al. Nonlinear seepage flow of ultralow permeability reservoirs. Pet. Explor. Dev. 2008, 35(5): 606-612.

Liu, H. The numerical simulation for multistage fractured horizontal well in low-permeability reservoirs based on modified Darcy’s equation. J. Pet. Explor. Prod. Technol. 2017, 7(3): 735-746.

Liu, H., Wu, S. The numerical simulation for multi-stage fractured horizontal well in low permeability reservoirs based on modified Darcy’s equation. Paper SPE 176269 Presented at SPE/IATMI Asia Pacific Oil & Gas Conference and Exhibition, Nusa Dua, Bali, Indonesia, 20-22 October, 2015.

Liu, W. Numerical simulation of nonlinear seepage flow in low-permeable reservoirs with moving boundaries. Qingdao, China University of Petroleum Doctoral Dissertation, 2013. (in Chinese)

Liu, W., Yao, J., Chen, Z., et al. Effect of quadratic pressure gradient term on a one-dimensional moving boundary problem based on modified Darcy’s law. Acta Mech. Sin. 2016, 32(1): 38-53.

Liu, W., Yao, J., Wang, Y. Exact analytical solutions of moving boundary problems of one-dimensional flow in semi-infinite long porous media with threshold pressure gradient. Int. J. Heat Mass Transf. 2012, 55(21-22): 6017-6022.

Lu, J. Pressure behavior of a hydraulically fractured well in tight gas formation with threshold pressure gradient. Paper SPE 152158 Presented at SPE Middle East Unconventional Gas Conference and Exhibition, Abu Dhabi, UAE, 23-25 January, 2012.

Lu, J. Pressure behavior of fractured gas wells in low-permeability reservoirs with threshold pressure gradient. STRPM 2014, 5(2): 171-178.

Prada, A., Civan, F. Modification of Darcy’s law for the threshold pressure gradient. J. Pet. Sci. Eng. 1999, 22(4): 237-240.

Song, H., Cao, Y., Yu, M., et al. Impact of permeability heterogeneity on production characteristics in water-bearing tight gas reservoirs with threshold pressure gradient. J. Nat. Gas Sci. Eng. 2015, 22: 172-181.

Sun, Q., Zhang, R., Zhang, Y., et al. Pressure transient analysis of the low permeability composite reservoir with threshold pressure gradient. Presented at Asia-Pacific Power and Energy Engineering Conference, Chengdu, China, 28-31 March, 2010.

Thomas, L.K., Katz, D.L., Tek, M.R. Threshold pressure phenomena in porous media. Soc. Petrol. Eng. J. 1968, 8(2): 174-184.

Tian, W., Li, A., Ren, X., et al. The threshold pressure gradient effect in the tight sandstone gas reservoirs with high water saturation. Fuel 2018, 226: 221-229.

Wang, X., Hao, M., Han, Y. Implication of the threshold pressure gradient and its application. Acta Petrolei Sinica 2013, 34(1): 188-191. (in Chinese)

Wang, X., Sheng, J. Effect of low-velocity non-darcy flow on well production performance in Shale and Tight oil reservoirs. Fuel 2017, 190: 41-46.

Wang, X., Zhu, G., Wang, L. Exact analytical solutions for moving boundary problems of one-dimensional flow in semi-infinite porous media with consideration of threshold pressure gradient. J. Hydrodyn. Ser. B 2015, 27(4): 542-547.

Wu, K., Li, X., Yang, P., et al. The Establishment of a novel deliverability equation of abnormal pressure gas reservoirs considering a variable threshold pressure drop. Pet. Sci. Technol. 2014, 32(1): 15-21.

Xiong, W., Lei, Q., Gao, S., et al. Pseudo threshold pressure gradient to flow for low permeability reservoirs. Pet. Explor. Dev. 2009, 36(2): 232-236.

Xu, J., Jiang, R., Xie, L., et al. Non-Darcy flow numerical simulation for low-permeability reservoirs. Paper SPE 154890 Presented at SPE Europec/EAGE Annual Conference, Copenhagen, Denmark, 4-7 June, 2012.

Zeng, B., Cheng, L., Hao, F. Experiment and mechanism analysis on threshold pressure gradient with different fluids. Paper SPE 140678 Presented at Nigeria Annual International Conference and Exhibition, Tinapa-Calabar, Nigeria, 31 July-7 August, 2010.

Zeng, B., Cheng, L., Li, C. Low velocity non-linear flow in ultra-low permeability reservoir. J. Pet. Sci. Eng. 2011, 80(1): 1-6.

Zeng, J., Wang, X., Guo, J., et al. Analytical model for multi-fractured horizontal wells in tight sand reservoir with threshold pressure gradient. Paper SPE 181819 Presented at SPE Asia Pacific Hydraulic Fracturing Conference, Beijing, China, 24-26 August, 2016.

Zeng, J., Wang, X., Guo, J., et al. Composite linear flow model for multi-fractured horizontal wells in tight sand reservoirs with the threshold pressure gradient. J. Pet. Sci. Eng. 2018, 165: 890-912.

Zhao, Y., Escobar, F.H., Jamili, A., et al. Effect of wellbore storage on the vertical well pressure behavior with threshold pressure gradient in low permeability reservoirs. ARPN-JEAS 2015a, 10(22): 10659-10665.

Zhao, Y., Zhang, L., Wu, F., et al. Analysis of horizontal well pressure behaviour in fractured low permeability reservoirs with consideration of the threshold pressure gradient. J. Geophys. Eng. 2013, 10(3): 35014-35023.

Zhao, Y., Zhang, L., Zhao, J., et al. Transient pressure analysis of horizontal well in low permeability oil reservoir. Int. J. Oil Gas Coal Technol. 2015b, 10(1): 23-38.

Zhu, W., Song, H., Huang, X., et al. Pressure characteristics and effective deployment in a water-bearing tight gas reservoir with low-velocity non-darcy flow. Energy Fuels 2011, 25(3): 1111-1117.