The present invention relates to the oil-and-gas industry, specifically, to the development and exploitation of oil reservoirs with various permeability zones, including by means of lateral horizontal bore segments. The method of interval action on horizontal wells includes the steps at which a horizontal segment of the wet is bored preliminarily, the same segment being constructed through the formation with various permeability zones. Geophysical survey is conducted and the number of the oil recovery intervals of various categories and their lengths are determined. A tail pipe (or tail filter) of the casing string with packers and drive shoe is lowered down and installed in the horizontal segment of the well. A pump and an assembly on the pipe string is lowered down into the well, the same assembly consisting of the electric valves with the pressure and temperature sensing devices, the cable and the packers separating the annular space of the well. The assembly packers are arranged opposite to the casing string packers. While lowering down the assembly, some electric valves are opened, and another electric valve (intended for circulation) is closed. The data obtained from the sensing devices are monitored. The formation segments are periodically treated by injecting a chemical composition into the corresponding interval of the well horizontal segment.

An injection well system is disclosed. The injection well system includes an injection wellhead having a lower master ball valve disposed at a first lower portion of the injection wellhead, an injection wellbore connected to the first lower portion of the injection wellhead, and a nonmetallic check valve disposed below the Earth's surface and at a pre-determined location of the injection wellbore, where the nonmetallic check valve, when closed, isolates the injection wellhead from a second lower portion of the injection wellbore.

A tubular defines a central flow passage. A camera has an aperture and attached to an outer surface of the tubular with the aperture oriented away from the outer surface of the tubular. A lost circulation media reservoir is circumferentially surrounding at least a portion of the outer surface of the tubular. The lost circulation media reservoir is adjacent to the camera. The lost circulation media reservoir includes actuable gates along a periphery of the lost circulation media reservoir. A trigger is communicably coupled with the actuable gates and configured to actuate the actuable gates.

A downhole tool includes a y-tubular section sized to run into a wellbore and configured to couple to a production tubing. The y-tubular section includes a main tubular section, a primary tubular leg coupled to the main tubular section, and a secondary tubular leg coupled to the main tubular section and offset from the primary tubular leg. The secondary tubular leg is sized to receive an electrical submersible pump (ESP). A hydraulic flow control device is positioned in the primary tubular leg and configured to selectively modulate toward an open position to fluidly couple the main tubular section to a portion of the primary tubular leg and selectively modulate toward a closed position to fluidly decouple the secondary tubular leg from a portion of the primary tubular leg based on a hydraulic signal from a hydraulic fluid system positioned at or near a terranean surface.

A pump system includes a pump barrel disposed within a housing. A standing valve is disposed at a first end of a pump chamber defined within the pump barrel. A traveling valve is disposed at a second end of the pump chamber. The traveling valve is movable relative to along an axial axis and relative to the housing. A motor stator is disposed inside the housing. produces a rotating electromagnetic field upon receiving electrical power. A motor rotor is rotatably supported within the motor stator and rotates about the axial axis in response to the rotating electromagnetic field. A traveling plug is coupled to the valve body of the traveling body and arranged to move linearly along the axial axis in response to rotation of the motor rotor. The pump system can be disposed in a wellbore to lift fluids up a tubing in the wellbore.

A system for delivering hydraulic fracturing fluid to a wellbore is provided. The system includes a first frac tree connected to a first wellbore and a second frac tree connected to second wellbore. The system further includes a zipper module and a first single straight-line connection between the zipper module and the first frac tree. The system also includes a second single straight-line connection between the first frac tree and the second frac tree.

A wellbore system includes method of cutting a casing in a wellbore. A string is disposed in the casing, the string including a cutting tool and an activation sub coupled to the cutting tool. The cutting tool includes a ball seat and a cutter. The activation sub includes a control piston disposed therein. The control piston has a ball at an end thereof. The control piston is configured to move within the activation sub to engage the ball to the ball seat when a flow rate of a fluid through the control piston is above a flow rate activation threshold, wherein engaging the ball to the ball seat creates a pressure differential across the ball seat that moves the ball seat to extend the cutter from the cutting tool.

An inhibitor injection spool is provided. The spool includes a segment of pipeline configured to convey crude oil and to couple with a pipeline system conveying crude oil. The spool also includes a valve on a top side or an underside of the segment of pipeline such that an interior of the segment of pipeline is selectively accessible from an exterior of the segment of pipeline. A solid corrosion inhibitor is configured to traverse an interior of the valve and such that it is positioned within the interior of the segment of pipeline such that at least a portion of the solid corrosion inhibitor fluidly contacts the crude oil traversing the segment of pipeline. Two mesh screens are coupled to the interior of the segment of pipeline such that crude oil traversing the segment of pipeline may not bypass either the first or second mesh screens.

A ball valve assembly includes a ball configured to rotate between an open position and a closed position. The ball valve assembly also includes a cradle having a ball-facing surface. The ball-facing surface faces the ball and is positioned at an end of a fluid passage through the cradle. In addition, the cradle is configured to rotatably support the ball to enable the ball to rotate between the open position and the closed position, and the cradle is configured to block movement of the ball toward the ball-facing surface to establish a separation distance between the ball and the ball-facing surface.

A completion string includes at least one isolation packer positioned between well zones of a plurality of well zones, and a sand control assembly and a circulating assembly each disposed uphole of a washdown shoe in the bottom-most well zone. A top well zone includes a return valve assembly, a production packer, and a second circulating assembly and a second sand control assembly downhole of the production packer. The completion string also includes an outer string spanning from the bottom-most well zone to the top well zone, and an inner production string concentrically arranged within the outer string, creating an inner-annulus between the outer string and inner production string. The inner-annulus is continuous from the washdown shoe to the return valve assembly, and the inner production string includes a production valve disposed between the sand control assembly and the circulating assembly in each of the bottom-most and top well zones.