A method includes placing a fluid in a treatment zone of a wellbore, the fluid in fluid communication with a near wellbore region of a subterranean formation. At least one energetic event generating material is placed in the wellbore, and positioned adjacent and up hole from the fluid. An energetic event is generated from the at least one energetic event generating material, and at least one fracture is formed in the near wellbore region from the at least one energetic event applying a pressure pulse onto the fluid. In some aspects, the fluid is a viscous pill.

A method and apparatus for containing one or more shaped charges in a single plane, arrayed about the center axis of a gun body, and detonated from a single initiator in a shaped charge cluster assembly.

This application describes a device for stimulating a geologic formation using an electrically throttled liquid propellant. The device may be used for primary stimulation, changing the direction of a fracture in a wellbore during hydraulic fracturing, a re-frac of an existing interval to open new areas in an open interval, or reset fracture conductivity after extended shut in of the well. This comprises deploying the device on tubing or wireline and positioning it close to the selected wellbore interval where liquid propellant can be selectively ignited. The device's controls release and ignite an energetic material that produces expanding gas to increase pressure and stimulate the selected interval. The device is comprised of a reservoir to hold energetic material, a metering system to release propellant at a desired rate, an electrical ignition source to control output, a no backflow valve, and control module that operates the metering and electrical ignition.

This application describes a device for stimulating a geologic formation using an electrically throttled liquid propellant. The device may be used for primary stimulation, changing the direction of a fracture in a wellbore during hydraulic fracturing, a re-frac of an existing interval to open new areas in an open interval, or reset fracture conductivity after extended shut in of the well. This comprises deploying the device on tubing or wireline and positioning it close to the selected wellbore interval where liquid propellant can be selectively ignited. The device's controls release and ignite an energetic material that produces expanding gas to increase pressure and stimulate the selected interval. The device is comprised of a reservoir to hold energetic material, a metering system to release propellant at a desired rate, an electrical ignition source to control output, a no backflow valve, and control module that operates the metering and electrical ignition.

A method of producing subterranean fractures in geologic formations having a significant amount of water present (a wet well) and/or at deep locations (1.5-2 miles or more) for the extraction of hydrocarbons therefrom includes flowing an explosive hydrophobic emulsion mixture to protect the air and fuel mixture subsequently flowed into a well hole. The build-up of pressure using a multiple plate restriction orifice assembly eventually causes auto-ignition of the air and fuel mixture which fractures the formation for recovery of the hyrdrocarbons.

A method of producing subterranean fractures in geologic formations having a significant amount of water present (a wet well) and/or at deep locations (1.5-2 miles or more) for the extraction of hydrocarbons therefrom includes flowing an explosive hydrophobic emulsion mixture to protect the air and fuel mixture subsequently flowed into a well hole. The build-up of pressure using a multiple plate restriction orifice assembly eventually causes auto-ignition of the air and fuel mixture which fractures the formation for recovery of the hyrdrocarbons.

This disclosure provides a stackable propellant module for use inside of a gas generation canister. The modules are designed to enable them to be individually fired rather than as a unitary mass, as done in conventional configurations. This enables the generation of a controlled pressure profile rather than an uncontrolled pressure profile determined by the environmental conditions downhole, such as temperature and pressure.

A method includes injecting an injection fluid through a well and to a depth of a formation, where the injection fluid includes phase-changing nanodroplets having a liquid core and a shell. The method also includes exposing the phase-changing nanodroplets to an external stimulus at the depth of the formation, wherein the liquid core of the phase-changing nanodroplets undergoes a liquid-to-vapor phase change causing the phase-changing nanodroplets to expand, and stimulating the formation at a near wellbore region by expansion of the phase-changing nanodroplets.

Methods and systems for creating fractures in rock are disclosed herein. In an exemplary method, reactive fluid is delivered into a wellbore. Formation fracture pressure is added to the reactive fluid in the wellbore sufficient to create a fracture network in a formation. The reaction pressure rubblizes the portion of a rock face of the fracture wall face to generate propping rubble that props the fracture open.

Methods and systems for creating fractures in rock are disclosed herein. In an exemplary method, reactive fluid is delivered into a wellbore. Formation fracture pressure is added to the reactive fluid in the wellbore sufficient to create a fracture network in a formation. The reaction pressure rubblizes the portion of a rock face of the fracture wall face to generate propping rubble that props the fracture open.