Shiguo Wu scite author profile

This paper analyzes the low production rate caused by the hydration of shale formations embedded into a naturally fractured reservoir. Results show that the induced stresses of shale hydration are the major reason to cause the permeability impairment for the stress sensitive reservoir. Experimental and numerical simulation methods for fracture closure and effect on permeability impairment discussed in the paper. Field application of the methods introduced in the paper also presented. Introduction In petroleum industry, people emphasize shale formation because it is a cover layer of a reservoir or it causes a lot of trouble during drilling. However, the hydration of shale formation under reservoir condition generates enormous hydration stresses which cause permeability impairment for stress sensitive reservoirs. There are three kinds of typical situations should be noted. First, the shale formation which has a very strong swelling tendency generates enormous hydration stress under reservoir condition. This hydration stress sometimes exceeds the overburden pressure. The permeability impairment for normal reservoirs can be as high as 10% to 40% under this condition. Second, the shale formation which does not have large swelling volume, but the reservoir is highly stress sensitive. A small swelling volume of the shale formation will introduce a large permeability impairment, such as a reservoir with horizontal fractures, coal bed with high density of cracks and loose sand reservoirs. Third, the shale formation has large swelling tendency and the formation is highly stress sensitive, such as coal bed. The shale swelling will cause dramatic reduction of permeability of a coal bed, which is the major problem in coal bed methane production in China. This paper focuses on the effect of shale hydration and swelling on permeability impairments for naturally fractured reservoir. The effect on porous reservoir will be discussed in other papers. Analysis of Fracture Closure Caused by Shale Swelling for Stress Sensitive Naturally Fractured Reservoir Physical models of fracture surface morphology There are four kinds of fractures; parallel, arc, multi-supports and conjugate network fracture. The parallel fracture can be characterized by that the both surfaces is parallel and smooth. Most tension fractures can be classified as this kind. Arc fracture has arcs on both fracture surfaces. Except that the end points of an arc contact, there are no contact points in the arc, such as fractures in volcanic fractured reservoir which is formed by the volcanic rock shrinkage due to cool process. Multi-supports fracture is the most seeing fracture, as indicated in Fig. 1. This fracture is formed by coaxial shear or compressive shear. Most horizontal and low angle fractures are this kind. Conjugate network fractures are formed either non-coaxial shear, horizontal compress or rock shrinkage (such as coal bed). For a single conjugate fracture, it can be classified as the multi-supporting fracture. In above fractures, the multi-supports fracture and conjugate fracture network are the most stress sensitive. The following paper will discuss the closure of the multi-supports fracture under shale hydration stress. The model of fracture closure The closure of the multi-supports fracture can be simulated by finite element method for a given stress and mechanical properties. For simplicity, the model shown in Fig. 2a was used. Fig. 2b shows the settlement of single support. This can be calculated by using the solution of H. Hertz problem.(1) P. 287

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Shiguo Wu

Accuracy of the staggered-grid finite-difference method of the acoustic wave equation for marine seismic reflection modeling

An effective method for shear-wave velocity prediction in sandstones

Affection of Shale Hydration for Stress Sensitive Gas Reservoir Production

Contact Info

Product

Resources

About