Abstract
Spontaneous imbibition of water-based fracturing fluids into the shale matrix is considered to be the main mechanism responsible for the high volume of water loss during the flowback period. Understanding the matrix imbibition capacity and rate helps to determine the fracturing fluid volume, optimize the flowback design, and to analyze the influences on the production of shale gas. Imbibition experiments were conducted on shale samples from the Sichuan Basin, and some tight sandstone samples from the Ordos Basin. Tight volcanic samples from the Songliao Basin were also investigated for comparison. The effects of porosity, clay minerals, surfactants, and KCl solutions on the matrix imbibition capacity and rate were systematically investigated. The results show that the imbibition characteristic of tight rocks can be characterized by the imbibition curve shape, the imbibition capacity, the imbibition rate, and the diffusion rate. The driving forces of water imbibition are the capillary pressure and the clay absorption force. For the tight rocks with low clay contents, the imbibition capacity and rate are positively correlated with the porosity. For tight rocks with high clay content, the type and content of clay minerals are the most important factors affecting the imbibition capacity. The imbibed water volume normalized by the porosity increases with an increasing total clay content. Smectite and illite/smectite tend to greatly enhance the water imbibition capacity. Furthermore, clay-rich tight rocks can imbibe a volume of water greater than their measured pore volume. The average ratio of the imbibed water volume to the pore volume is approximately 1.1 in the Niutitang shale, 1.9 in the Lujiaping shale, 2.8 in the Longmaxi shale, and 4.0 in the Yingcheng volcanic rock, and this ratio can be regarded as a parameter that indicates the influence of clay. In addition, surfactants can change the imbibition capacity due to alteration of the capillary pressure and wettability. A 10 wt% KCl solution can inhibit clay absorption to reduce the imbibition capacity.
Highlights
Multistage hydraulic fracturing is a critical technology for economic production from shale reservoirs
The results show that the imbibition characteristic of tight rocks can be characterized by the imbibition curve shape, the imbibition capacity, the imbibition rate, and the diffusion rate
This paper focuses on the imbibition capacity and the influence of the mineral composition and physical properties of tight rocks
Summary
Multistage hydraulic fracturing is a critical technology for economic production from shale reservoirs. In the U.S Haynesville shale formation, the flowback rate is even lower than 5 % after fracturing operations (Penny et al 2006). Studying the imbibition capacity and its main controlling factors is essential to understanding reservoir performance and optimizing fracturing operations. Roychaudhuri et al (2013) determined that a surfactant can effectively reduce the imbibition rate of fracturing fluids, and the driving force of imbibition is the capillary pressure. The imbibition capacity, imbibition rate, and other influencing factors in shale reservoirs have not been investigated systematically. This paper focuses on the imbibition capacity and the influence of the mineral composition and physical properties of tight rocks. In group 1, the imbibition capacity and rate of deionized water uptake are investigated systematically. In group 3, comparative experiments are conducted to explore the effects of different fluids on the imbibition capacity
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