Impact of chemical osmosis on water leakoff and flowback behavior from hydraulically fractured gas shale

In this paper, the development of a comprehensive multi-mechanistic multi-porosity water/gas/salt flow model to investigate the leakoff and flowback behavior of the fracturing fluid from hydraulically fractured shale gas wells is presented. The multi-mechanistic model takes into account water transp...

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Bibliographic Details
Published in:Journal of petroleum science & engineering 2017-03, Vol.151, p.264-274
Main Authors: Wang, Fei, Pan, Ziqing, Zhang, Shicheng
Format: Article
Language:English
Subjects:
Chemical osmosis
Flowback
Fracturing-fluid
Leakoff
Shale
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Summary:In this paper, the development of a comprehensive multi-mechanistic multi-porosity water/gas/salt flow model to investigate the leakoff and flowback behavior of the fracturing fluid from hydraulically fractured shale gas wells is presented. The multi-mechanistic model takes into account water transport induced by hydraulic pressure driven convection, osmosis pressure driven convection and capillary imbibition, gas transport induced by both hydraulic pressure driven convection and desorption, and salt transport induced by advection and concentration driven diffusion. In the multi-porosity model, hydraulic fractures are considered as a interconnected continuum embedded in shale matrix, where organic shale is interspersed within vast inorganic shale. The organic matrix is thus considered disconnected in the entire reservoir. The water saturation profiles for chemical osmosis-induced, capillary pressure-induced and hydraulic pressure-induced cases are compared, revealing a region of saturation that effectively is immobile even though irreducible saturation has not been reached. In sensitivity analyses, cases with different hydraulic pressure, injected fluid salinity and salt diffusion coefficient are considered.The results indicate that chemical osmosis intensifies water leakoff and hinders water flowback. Further, chemical osmosis is a key mechanism for water retention after the treatment of hydraulic fracturing and should not be ignored especially in flowback data analysis of hydraulically fractured shale gas wells. •A comprehensive multi-mechanistic multi-porosity water/gas/salt flow model is established based on the shale properties.•A numerical simulation of fracturing-fluid leakoff and flowback in a hydraulically fractured shale gas well is also conducted using the proposed model.•Sensitivity analyses are performed to further investigate the chemiosmosis, capillarity and hydraulic pressure respectively on the water flow behaviors.•Results indicate that chemiosmosis intensifies water leakoff and hinders water flowback during the treatment of hydraulic fracturing.
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2017.01.018