Monitor the process of shale spontaneous imbibition in co-current and counter-current displacing gas by using low field nuclear magnetic resonance method

Abstract Large scale fracturing fluid is injected into the formation to produce fractures for the effective development of shale reservoir. However, the flow back rate of fracturing fluid is often less than the half of the injected liquid, which causes large number of fracturing fluid retaining in the shale reservoir, thus aqueous phase trapping (APT) appears. But after well was shut in for a period of time, the APT can be auto-removed. The experiments that monitored the process of shale spontaneous imbibition in co-current and counter-current displacing gas combined with nuclear magnetic resonance (NMR) were performed. Results show that no matter whether the spontaneous imbibition of sandstone and volcanic rock happened in co-current or counter-current displacing gas, the water content increases in the whole pores range gradually, and no preferential pores for spontaneous imbibition appear. The water content increases with convex curve in the early period of both conditions. Simultaneously, in the process of the experiments no apparent micro cracks appeared on the surfaces of the sandstone and volcanic rock. However, shale has some special characteristics in spontaneous imbibition of both co-current and counter-current displacing gas, which may contribute to the auto-removal mechanism of shale reservoir APT. During the experiments of shale, lots of micro cracks appeared on the surface of the sample gradually. The liquid absorbed into the shale sample fills the micro pores firstly. Subsequently the water takes up the space of mesopores slowly. The liquid in the large pores of shale is too small to be detected, so the water content change in these pores couldn't be distinguished clearly. In the early period, the water content of shale increases with convex curve in the co-current displacing gas, while the water content of shale increases linearly in the counter-current displacing gas. Thus, the counter-current spontaneous imbibition condition is beneficial to protect the reservoir. The results of our study contribute to not only explaining the auto-removal mechanism of shale reservoir APT, but also fixing the optimal flow-back time after hydraulic fracturing.

[1]  L. Ayala,et al.  Experimental investigation of shale gas production impairment due to fracturing fluid migration during shut-in time , 2015 .

[2]  D. Dewhurst,et al.  Laboratory characterisation of shale properties , 2012 .

[3]  Basabdatta Roychaudhuri,et al.  An experimental investigation of spontaneous imbibition in gas shales , 2013 .

[4]  R. Marc Bustin,et al.  Characterization of gas shale pore systems by porosimetry, pycnometry, surface area, and field emission scanning electron microscopy/transmission electron microscopy image analyses: Examples from the Barnett, Woodford, Haynesville, Marcellus, and Doig units , 2012 .

[5]  D. Standnes Experimental Study of the Impact of Boundary Conditions on Oil Recovery by Co-Current and Counter-Current Spontaneous Imbibition , 2004 .

[6]  Lizhi Xiao,et al.  NMR logging : principles and applications , 1999 .

[7]  Dongmei Wang,et al.  Flow-Rate Behavior and Imbibition in Shale , 2011 .

[8]  K. Mirotchnik,et al.  Low-Field NMR Method for Bitumen Sands Characterization: A New Approach , 2001 .

[9]  Yueming Cheng Impact of Water Dynamics in Fractures on the Performance of Hydraulically Fractured Wells in Gas-Shale Reservoirs , 2012 .

[10]  D. B. Bennion,et al.  Water And Hydrocarbon Phase Trapping In Porous Media-Diagnosis, Prevention And Treatment , 1996 .

[11]  Mian Chen,et al.  Reactivation mechanism of natural fractures by hydraulic fracturing in naturally fractured shale reservoirs , 2015 .

[12]  Gang Yu,et al.  Applications Of NMR Mud Logging Technology In China , 2007 .

[13]  A. Hayatdavoudi,et al.  Post Frac Gas Production through Shale Capillary Activation , 2015 .

[14]  Xiangjun Liu,et al.  Experimental study on crack propagation in shale formations considering hydration and wettability , 2015 .

[15]  Sheng Chen,et al.  Sensitivity analysis of geometry for multi-stage fractured horizontal wells with consideration of finite-conductivity fractures in shale gas reservoirs , 2015 .

[16]  Ali Saeedi,et al.  Tight gas sands permeability estimation from mercury injection capillary pressure and nuclear magnetic resonance data , 2012 .

[17]  Hao Xu,et al.  A precise measurement method for shale porosity with low-field nuclear magnetic resonance: A case study of the Carboniferous-Permian strata in the Linxing area, eastern Ordos Basin, China , 2015 .

[18]  George E. King,et al.  Hydraulic Fracturing 101: What Every Representative, Environmentalist, Regulator, Reporter, Investor, University Researcher, Neighbor and Engineer Should Know About Estimating Frac Risk and Improving Frac Performance in Unconventional Gas and Oil Wells , 2012 .

[19]  Fang Hao,et al.  Mechanisms of shale gas storage: Implications for shale gas exploration in China , 2013 .

[20]  L. Cathles,et al.  The fate of residual treatment water in gas shale , 2014 .

[21]  H. Dehghanpour,et al.  Liquid uptake of gas shales: A workflow to estimate water loss during shut-in periods after fracturing operations , 2014 .

[22]  Q. Lan,et al.  Spontaneous Imbibition of Brine and Oil in Gas Shales: Effect of Water Adsorption and Resulting Microfractures , 2013 .

[23]  Guochang Wang,et al.  Early Paleozoic shale properties and gas potential evaluation in Xiuwu Basin, western Lower Yangtze Platform , 2015 .

[24]  C. Liang,et al.  The shale characteristics and shale gas exploration prospects of the Lower Silurian Longmaxi shale, Sichuan Basin, South China , 2014 .

[25]  S. Bryant,et al.  Pore structure of shale , 2015 .

[26]  J. Birdwell,et al.  Application of binomial-edited CPMG to shale characterization. , 2014, Journal of magnetic resonance.

[27]  N. Morrow,et al.  Spontaneous Counter-Current Imbibition into Core Samples with All Faces Open , 2009 .