A non-electric explosive device includes a primary body containing cutting material and including a primary charge positioned in the cutting material; an explosive body at a first axial end of the primary body and including explosive material; and a firing head at a second axial end of the primary body, the firing head including a firing pin secured at least partially inside the firing head via securing device, the firing pin comprising an activating end proximate the primary charge and a blunt end protruding from a distal end of the firing head. A force applied to the blunt end of the firing pin causes the firing pin to retract toward the primary charge and break the securing device so that the activating end of the retracting firing pin impacts the primary charge which ignites the explosive material that causes the cutting material in the primary body to travel radially outward.

A method of removing material from a target is described. The method comprises the steps of providing a tool, the tool having at least one propellant source; pressurising the tool to a pressure higher than the environmental pressure; igniting at least one of the propellant source(s) to form a combustion zone; and directing combustion products generated at the combustion zone along at least one tool flow path. The tool flow path(s) is selectively openable or closable, such that upon exiting the tool flow path(s) the combustion products interact with a target, the interaction causing material to be removed from the target.

An engineered composite system designed to be passive or inert under one set of conditions, but becomes active when exposed to a second set of conditions. This system can include a dissolving or disintegrating core, and a surface coating that has higher strength or which only dissolves under certain temperature and pH conditions, or in selected fluids. These reactive materials are useful for oil and gas completions and well stimulation processes, enhanced oil and gas recovery operations, as well as in defensive and mining applications requiring high energy density and good mechanical properties, but which can be stored and used for long periods of time without degradation.

A drilling assembly (1) for making a passage in an object (2) within a petroleum well (8). The drilling assembly (1) comprises a drill bit assembly (3), a cutting assembly (4), and both assemblies (3, 4) are fastened to a rotatable drive assembly (5), the drill bit assembly (3) comprises a drill bit (31); the cutting assembly (4) comprises a hole saw assembly (42); the cutting assembly (4) is resiliently displaceable to the drill bit assembly (3). The drilling assembly (1) comprises a displaceable membrane (6) within the tubular body (41). The membrane (6) divides an interior (43) of the tubular body (41) in a receiving compartment (69) and an inner compartment (60).

A system includes a deployment device and an adjustable mill. The deployment device has a box end with internal threads. The adjustable mill has a tubular body, a cylinder, and a lock ring. The tubular body has a lateral end and a pin end. The pin end has external threads, the lateral end is partially enveloped by cutters, and the lateral end comprises an inner wall defining an orifice. The cylinder is movably disposed within the orifice. The cylinder is partially enveloped by the cutters. The lock ring is disposed circumferentially around the cylinder. The lock ring interacts with a lock ring seat machined into the inner wall of the lateral end to place the adjustable mill in a mode. The internal threads of the adjustable mill and the external threads of the deployment device interact to form a connection between the adjustable mill and the deployment device.

Provided, in one aspect, is a method for forming a well system. The method, in one aspect, includes forming a wellbore within a subterranean formation, and positioning an anchoring subassembly within the wellbore. The method, according to this aspect, further includes washing over at least a portion of the anchoring subassembly with a washover assembly, and then removing the washed over anchoring subassembly from the wellbore.

A system includes a deployment device and an adjustable mill. The deployment device has a box end with internal threads. The adjustable mill has a tubular body, a cylinder, and a lock ring. The tubular body has a lateral end and a pin end. The pin end has external threads, the lateral end is partially enveloped by cutters, and the lateral end comprises an inner wall defining an orifice. The cylinder is movably disposed within the orifice. The cylinder is partially enveloped by the cutters. The lock ring is disposed circumferentially around the cylinder. The lock ring interacts with a lock ring seat machined into the inner wall of the lateral end to place the adjustable mill in a mode. The internal threads of the adjustable mill and the external threads of the deployment device interact to form a connection between the adjustable mill and the deployment device.

Systems and methods for cutting objects within a subterranean well include a laser system having a laser drilling head located at a terminal downhole end of a laser tool body directing a head laser beam in a direction downhole. A laser scanner assembly located within the laser tool body has a scanner head directing a scanner laser beam and can move both axially along a length of the laser tool body and rotate around a central axis of the laser tool body. A laser cutter assembly located within the laser tool body has a cutter head directing a cutter laser beam and can rotate around the central axis of the laser tool body. A cable bundle formed of a plurality of fiber optic cables extends from an uphole end of the laser tool body to each of the laser drilling head, the laser scanner assembly, and the laser cutter assembly.

A wellbore assembly includes a cable configured to be disposed within a wellbore. The wellbore assembly also includes a housing attached to a downhole end of the cable. The housing defines a fluid outlet at a downhole end of the housing. The housing includes an anchor and a collapsible gate. The anchor engages a wall of the wellbore under increased tension in the cable, thereby anchoring the housing to the wellbore. The collapsible gate is disposed inside the housing between an uphole end of the housing and the fluid outlet. The housing temporarily stores a treatment fluid configured to treat an obstruction in the wellbore. The collapsible gate is configured to break, with the anchor engaged, under further tension applied by the cable, inside the housing to allow the treatment fluid to flow out of the housing through the fluid outlet toward the obstruction.

An engineered composite system designed to be passive or inert under one set of conditions, but becomes active when exposed to a second set of conditions. This system can include a dissolving or disintegrating core, and a surface coating that has higher strength or which only dissolves under certain temperature and pH conditions, or in selected fluids. These reactive materials are useful for oil and gas completions and well stimulation processes, enhanced oil and gas recovery operations, as well as in defensive and mining applications requiring high energy density and good mechanical properties, but which can be stored and used for long periods of time without degradation.