A dual function ram system for a blowout preventer (BOP) includes a first dual function ram that is configured to move within a cavity of the BOP between a withdrawn position to cause the BOP to be in an open configuration and an extended position to cause the BOP to be in a closed configuration. The first dual function ram includes a shearing surface that is configured to shear a tubular within a central bore during a shearing operation and a pipe-sealing surface that is configured to seal against the tubular within the central bore during a pipe-sealing operation.

A dual function ram system for a blowout preventer (BOP) includes a first dual function ram that is configured to move within a cavity of the BOP between a withdrawn position to cause the BOP to be in an open configuration and an extended position to cause the BOP to be in a closed configuration. The first dual function ram includes a shearing surface that is configured to shear a tubular within a central bore during a shearing operation and a pipe-sealing surface that is configured to seal against the tubular within the central bore during a pipe-sealing operation.

This disclosure provides a hybrid well capping stack system that uses a lower ram blow-out preventer (BOP) coupled to a gate valve-based capping stack that has first and second flowlines where the first flowline has a gate valve and the second flowline has a gate valve. At least one of the first and second flowlines is located on the frame to divert a flow of fluid laterally from a central flow axis of a wellbore.

A control system for controlling disconnection of riser system that extends between a vessel and a subsea location that comprises a wellbore, the riser system configured to receive a string in use, the control system being configured to disconnect the riser system according to a sequence of operations, the sequence of operations comprising disconnecting the riser system prior to or simultaneous with cutting the string and sealing the well bore.

An adjustable blowout preventer may be configured to be adjustable, such that a central bore of the blowout preventer may be adjusted or repositioned. The blowout preventer may include one or more adjustment mechanisms for adjusting an angle of tilt of the central bore and/or an offset distance of the central bore. The adjustment mechanisms may be arranged between a stack of the blowout preventer and a wellhead. The adjustment mechanisms may generally be tubular structures having angled and/or laterally offset bores therein. The adjustment mechanisms may be configured to be rotatable, such that rotation of the mechanisms may change an angle of tilt and/or lateral offset of the blowout preventer central bore, or portions thereof.

A system for locking a bearing assembly to a rotating control device (RCD) housing is provided. The RCD housing can be coupled to a blowout preventer, and the bearing assembly can be received within the housing, and can comprise a stationary bearing housing having a perimeter channel. A plurality of locking block assemblies are each supported by the housing and are operable between a locked position and an unlocked position. Each locking block assembly comprises a movable block configured to interface with the perimeter channel when in the locked position, and at least one elastic component is situated between the housing and the movable block. The at least one elastic component is configured to automatically bias the movable block in the locked position. Upon supplying fluid pressure via a valve device, the movable block moves to the unlocked position and the at least one elastic component compresses to facilitate removal of the bearing assembly from the RCD housing. Associated systems and methods are provided.

A blow out preventer bonnet removal method is provided for removing a bonnet from the body of a blow out preventer. The method includes attaching a rail system to the body that extends laterally away from the body. A carriage apparatus is mounted on the rail system. A saddle is connected to the bonnet. The bonnet is then detached from the body. The bonnet is then moved on the rail system from a first position next to the body to a second position spaced away from the body. The carriage apparatus transports the bonnet upon the rail system when moving from the first to the second position.

A blowout preventer (BOP) for controlling pressure within a wellbore includes a body having a front side and a back side, the front side being opposite the back side. The BOP also includes a door opening extending through the front side. The BOP further includes an operator opening extending through the body, perpendicular to the door opening. The BOP includes an outlet extending from an inner cavity of the body through the back side, the inner cavity being fluidly coupled to both the outlet and the door opening. The BOP also includes a ram passage forming at least a portion of the inner cavity, wherein the ram passage is arranged substantially perpendicular to the door opening.

A blowout preventer (BOP) for controlling pressure within a wellbore includes an internal cavity and a front side including a door opening, the door opening providing access to the internal cavity. The BOP also includes a door assembly associated with the door opening. The door assembly includes a door, movable between a first position and a second position, the door blocking access to the internal cavity in the first position and enabling access to the internal cavity in the second position. The door assembly also includes a hinge coupled to the door to facilitate movement of the door between the first position and the second position. The door assembly further includes a coupling device associated with the door, the coupling device securing the door to the front side. The BOP also includes a back side including an outlet, the outlet being fluidly coupled to the internal cavity.

An improved emergency power system is disclosed for providing electrical power to a load such as a blowout preventer of a petroleum drilling apparatus. The improved emergency power system comprises a thermal battery having an anode and a cathode with a separator containing an electrolyte disposed therebetween. An internal heat layer is located in proximity to the separator containing the electrolyte. A squib is provided for activating the internal heat layer. The thermal battery remains dormant until the squib is energized to ignite the squib enabling the heat layer to render the electrolyte molten thereby activating battery to provide electrical power to the load. The squib may be energized remotely, mechanically or electrically.