A tool trap system that includes a housing. The housing defines a bore. A shaft couples to the housing. A flapper couples to the shaft. The flapper rotates with the shaft between an open position and a closed position to control movement of a wireline tool through the bore. An actuation system couples to the shaft. The actuation system rotates the shaft. The actuation system includes a lever that couples to and rotates the shaft. A cylinder contacts the lever. The cylinder moves axially along a longitudinal axis of the cylinder to rotate the lever.

An apparatus (10; 110; 310) for conveying a tool (12; 112; 312) into and/or from a well installation (W) comprises a conveying arrangement (16; 116; 316) configured for coupling to a housing (14; 114; 314) for receiving the tool to be conveyed (12; 112; 312). The conveying arrangement (16; 116; 316) includes an actuator arrangement (28; 128; 328) configurable between a retracted configuration and an extended configuration. The apparatus (10; 110; 310) is configured for location on a wellhead (WH) of the well installation (W), movement of the actuator arrangement (28; 128; 328) between the retracted configuration and the extended configuration moving the tool to be conveyed (12; 112; 312) into and/or from the housing (14; 114; 314) and thus into and/or from the well installation (W).

A flow tube for a control head for an apparatus (1) for forming a liquid seal around a conduit, cable or wire for intervention into a well, the flow tube comprising a flexible body (16) capable of stretching to accommodate localised variations in the external diameter of the conduit, cable or wire while maintaining a close contact with the external surface of the conduit, cable or wire.

A tool trap system includes a housing defining a bore, a shaft coupled to the housing, and a flapper and an actuation system coupled to the shaft. The flapper selectively obstructs the bore through the housing. The actuation system includes a lever coupled to and configured to rotate the shaft, a cylinder configured to contact the lever, a hydraulic cylinder, and a piston rod extending through the cylinder and the hydraulic cylinder. The cylinder is configured to move axially along a longitudinal axis of the cylinder to rotate the lever. In response to manual actuation of the tool trap system, the hydraulic cylinder remains in place as the cylinder moves axially. In response to powered actuation of the tool trap system, a fluid pumped into the hydraulic cylinder axially moves the hydraulic cylinder, and the piston rod remains in place as the cylinder moves axially.

A slickline stuffing box shock absorber is disclosed. The slickline stuffing box shock absorber includes a first mechanical component adapted to connect to a slickline in a wellbore, an upper rod rigidly coupled to the first mechanical component, a second mechanical component adapted to connect to a rope socket of a tool string in the wellbore, a lower rod rigidly coupled to the second mechanical component, and a spring adapted to absorb shock energy from the tool string so as to prevent breakage of the slickline, where the upper rod is hollow and has a larger inner diameter than an outer diameter of the lower rod to allow sliding movement of the lower rod inside the upper rod, and where the upper rod and the lower rod are elastically coupled to each other by the spring.

A slickline stuffing box shock absorber is disclosed. The slickline stuffing box shock absorber includes a first mechanical component adapted to connect to a slickline in a wellbore, an upper rod rigidly coupled to the first mechanical component, a second mechanical component adapted to connect to a rope socket of a tool string in the wellbore, a lower rod rigidly coupled to the second mechanical component, and a spring adapted to absorb shock energy from the tool string so as to prevent breakage of the slickline, where the upper rod is hollow and has a larger inner diameter than an outer diameter of the lower rod to allow sliding movement of the lower rod inside the upper rod, and where the upper rod and the lower rod are elastically coupled to each other by the spring.

A method for installing an electric submersible pump (ESP) in a well includes installing a plug in the well below a well tree. An upper and lower master valve on the tree are closed. Closure elements are removed from the lower master valve and replaced with gate seats, and a replacement gate block. The replacement gate block has a seat for a cable hanger. The upper master valve is opened. The plug is removed and the ESP extended into the well on an electrical cable. A cable hanger is affixed to the cable and is seated in the seat. The cable hanger has sealing elements to engage the seat and an electrical connector. The electrical connector is oriented to enable access through a side opening in the replacement gate block.

A method for installing an electric submersible pump (ESP) in a well includes installing a plug in the well below a well tree. An upper and lower master valve on the tree are closed. Closure elements are removed from the lower master valve and replaced with gate seats, and a replacement gate block. The replacement gate block has a seat for a cable hanger. The upper master valve is opened. The plug is removed and the ESP extended into the well on an electrical cable. A cable hanger is affixed to the cable and is seated in the seat. The cable hanger has sealing elements to engage the seat and an electrical connector. The electrical connector is oriented to enable access through a side opening in the replacement gate block.

A method and apparatus for transporting a capping stack for use in a subsea structure includes a capping stack having a capping stack spool, a connector body connectable to the capping stack spool and at least one diverter leg connectable to the capping stack spool. A first skid receives the capping stack spool on a floor thereof. A second skid receives the connector body on a floor thereof. A third skid receives the diverter leg thereon. The first, second and third skids are adapted to be received within an interior of an aircraft. The skids and the connected components can then be flown by the aircraft to a desired location so as to be assembled at a location near a wellhead.

An apparatus for fitting to a wellbore is provided. The apparatus includes a battery-powered downhole tool for deployment within the wellbore. The downhole tool includes a battery for providing electrical power to one or more components of the downhole tool. The apparatus further includes a lubricator for fitting to a wellhead of the wellbore via a valve system providing communication between the lubricator and the wellbore, and for housing the downhole tool when in a stowed position. The lubricator includes a transmitter for receiving electrical power from a remote power source, and for transferring received electrical power to a receiver. The downhole tool includes a receiver for providing electrical power to the battery, and for receiving electrical power from the transmitter. A method of transferring power from a transmitter of a lubricator to a receiver of a downhole tool is also provided.