A sidetrack window is cut in a cased wellbore by disposing a sidetracking assembly within the cased wellbore. A first ball is deployed into a drill string of the sidetracking assembly. The first ball leaves the drill string and lands on a ball seat of a cement retainer to block fluid outlet of the cement retainer. Then, the cement retainer is set and a second fluid outlet of the cement retainer is exposed. Cement is flowed through the drill string to the portion of the cased wellbore downstream of the cement retainer to plug the portion of the wellbore. The whipstock assembly is separated from the cement retainer. A second ball is deployed inside the drill string to land on the seat of the whipstock assembly to block a fluid outlet of the whipstock assembly. The whipstock assembly is anchored in the cased wellbore and the milling system is actuated to begin cutting the sidetrack window.

A sidetrack window is cut in a cased wellbore by disposing a sidetracking assembly within the cased wellbore. A first ball is deployed into a drill string of the sidetracking assembly. The first ball leaves the drill string and lands on a ball seat of a cement retainer to block fluid outlet of the cement retainer. Then, the cement retainer is set and a second fluid outlet of the cement retainer is exposed. Cement is flowed through the drill string to the portion of the cased wellbore downstream of the cement retainer to plug the portion of the wellbore. The whipstock assembly is separated from the cement retainer. A second ball is deployed inside the drill string to land on the seat of the whipstock assembly to block a fluid outlet of the whipstock assembly. The whipstock assembly is anchored in the cased wellbore and the milling system is actuated to begin cutting the sidetrack window.

A system includes a downhole acquisition tool housing that may receive a fluid that enters the downhole acquisition tool from a first flowline, a second flowline, or both. The system includes a flow control device removably coupled to the downhole acquisition tool. The flow control device may include a housing, a plurality of flow routing plugs that may be in fluid communication to the first flowline, the second flowline, or both, and channels disposed within the housing and fluidly coupled to the plurality of flow routing plugs.

A wellbore self-retrievable tool for conveying and releasing a load in a well, such as for wellbore abandonment, wherein the load is a resin for producing a set resin plug. The tool comprises: a floatation device; a load carrier, such as a payload tube; and a load release mechanism, the floatation device being configured to render the tool buoyant in a wellbore liquid.

The present invention relates to an annular barrier for being expanded in an annulus between a well tubular structure and a wall of a borehole or another well tubular structure downhole for isolating a first zone from a second zone in the annulus, the annulus having an annulus pressure, the annular barrier comprising: a tubular part for being mounted as part of the well tubular structure, the tubular part comprising an inside having an inside pressure, an expandable sleeve surrounding the tubular part and having an inner face facing the tubular part and an outer face facing the borehole or the wall, each end of the expandable sleeve being connected with the tubular part, an annular space between the inner face of the expandable sleeve and the tubular part, the annular space having a space pressure, and a valve system having a first system position in which fluid communication is provided between the inside of the tubular part and the annular space and a second system position in which fluid communication is provided between the annular space and the annulus, and a space fluid channel fluidly connecting the valve system with the annular space and which annular space in the first system position is fluidly connected with the inside of the tubular part and the annular space in the second system position is fluidly connected with the annulus, wherein the annular barrier further comprises an expansion indication unit and a chamber having a chamber pressure which is lower than a predetermined first pressure, the expansion indication unit has a first port in fluid communication with the space fluid channel, a second port in fluid communication with the chamber and a third port in fluid communication with the inside of the tubular part, the expansion indication unit has a first unit position in which the second port is fluidly disconnected from the third port and a second unit position in which the second port is fluidly connected with the third port. The present invention also relates to a downhole system and to an expansion detection method.

The present invention relates to an annular barrier for providing zonal isolation within a tubular structure or a borehole and for sealing off a first zone from a second zone, comprising a tubular metal part configured to be mounted as part of a well tubular metal structure, the tubular metal part having an outer face, an opening and an axial direction along the well tubular metal structure, a first expandable metal sleeve surrounding the tubular metal part and having a first end connected with the outer face of the tubular metal part and a second end, a second expandable metal sleeve surrounding the tubular metal part and having a first end connected with the outer face of the tubular metal part and a second end, wherein the first expandable metal sleeve and the second expandable metal sleeve each has an end section at the second end, the end section of the first expandable metal sleeve is at least partly overlapping the end section of the second expandable metal sleeve along the axial direction creating an overlapping area, the end sections are configured to slide in relation to each other, the first expandable metal sleeve and the second expandable metal sleeve define an annular space together with the tubular metal part, the first expandable metal sleeve extends from the second end of the first expandable metal sleeve away from the overlapping area in a first direction along the axial direction, and the second expandable metal sleeve extends from the second end of the second expandable metal sleeve away from the overlapping area in a second direction opposite the first direction.

An inflating container filled with formation plugging fluid is deployed at the target zone by a rigless apparatus. The inflating container can be in valved fluid communication with an explosive filled container, the explosive being ignited using a firing mechanism that is attached to the explosive filled container. The explosion expands gases in the explosive filled container which pass into the inflation container and displace the formation plugging fluid into the balloon sections and through the weakened portions of the central balloon to penetrate the walls of the target zone. The expanded central balloon is melted by the heat of the chemical reaction and a portion adheres to the formation wall thereby sealing the undesirable target zone; thereafter, the remaining balloon sections are deflated or ruptured to permit the apparatus to be withdrawn through the production tubing.

A tool and method to remove sand and other types of solid particulate materials and fluids from wellbores and conduits, resulting from well-drilling, well-production or both, and consequently to reactivate well production. The modular tool, composed of different subsystems, is connected to the end of concentric coil tubing, operates promoting the aggregates disintegration by using a spiral jet to impact these solids and suctioning the small particles and well fluids, simultaneously or later, by using jet pumps based on a set of several venturis. Changes between different operation modes are imposed by modifying surface pump pressure levels and the tool does not need to be removed from the wellbore between different stages, reducing the overall operation time.

An inflating container filled with formation plugging fluid is deployed at the target zone by a rigless apparatus. The inflating container can be in valved fluid communication with an explosive filled container, the explosive being ignited using a firing mechanism that is attached to the explosive filled container. The explosion expands gases in the explosive filled container which pass into the inflation container and displace the formation plugging fluid into the balloon sections and through the weakened portions of the central balloon to penetrate the walls of the target zone. The expanded central balloon is melted by the heat of the chemical reaction and a portion adheres to the formation wall thereby sealing the undesirable target zone; thereafter, the remaining balloon sections are deflated or ruptured to permit the apparatus to be withdrawn through the production tubing.

The present invention relates to a drill pipe expansion assembly (1) for expansion of a completion component (3) located at a fixed position in a well (4) having a longitudinal axis (5), the drill pipe expansion assembly comprising an expansion unit (6) which is moveable in relation to the completion component comprising a tubular element (7) comprising a first end (8) and a second end (10) and a wall (11) having an outer face (12) and an outlet (14) for ejection of pressurised fluid, and a first sealing element (15,15a) and a second sealing element (15, 15b) arranged on the outer face on each side of the outlet, and a positioning unit (20) comprising a body (21) and a first fixation element (22) movable between a projected position and a retracted position in relation to the body, the positioning unit being connected with the tubular element in order to maintain the expansion unit in a fixed position in relation to the completion component (3) during expansion. The present invention further relates to a downhole system.