The present disclosure relates to a system that includes a shearing ram configured to mount in a blowout preventer, wherein the shearing ram includes a body portion with a tapered surface, where the body portion includes a first hardness, and a ledge extending from an end of the tapered surface to form an edge, where the ledge includes a second hardness, greater than the first hardness.

A method to create a simulation of a shearing process for a ram blowout preventer (BOP) comprising the steps of building a 3D digital model of the ram BOP including damage parameters based on generic material properties of the ram BOP; inputting the 3D digital model of the ram BOP into a damage model; and simulating the shearing process using the 3D digital model of the ram BOP and the damage model.

Embodiments disclosed include BOP systems and methods for actuation of a BOP function by manipulating a component associated with a BOP. Embodiments of the disclosed BOP systems and the methods of operation of the BOP systems are further configured to monitor and/or control the actuation of a BOP function, by receiving information related to the actuation from a set of sensors associated with the component. Embodiments of the systems and/or methods include modeling actuation of the component; the actuation of the component being based on analyses derived from the modeling.

A blowout preventer and method of closing a wellbore. The blowout prevented has a main body containing a wellbore, a passage transverse to the wellbore, a shearing device located in the passage; and a charge that, when activated, propels the shearing device along the passage and across the wellbore to close the wellbore and prevent a blowout.

The invention relates to a well bore control apparatus, system and method for sealing a well bore. The invention relates to a well bore control apparatus (20) comprising a housing (27) having a guide element (36) defining a path, the housing defining a throughbore (23) for receiving a tubular, a first tapered gate (64a) and a tapered second gate (64b) located within the housing, the first and second gates being adapted to engage with the guide element. In use the first and second gates are moveable along the path defined by the guide element in a direction substantially transverse to the throughbore between an open position of the throughbore and a closed position of the throughbore. The well bore control apparatus comprises a first seal seat (42) for forming a first seal with the first gate in the closed position to seal the throughbore. The well bore control apparatus may include a second seal seat (44). The second seal seat may be adapted for forming a second seal with the second gate in the closed position to seal the throughbore.

A shear ram system includes an upper block positioned to transition from a first location outside a bore to a second location within the bore, the upper block including a blade control arm having a first contact surface. The shear ram system includes a lower block positioned to transition from the first location outside the bore to the second location within the bore, the lower block including a second contact surface proximate the first contact surface. The shear ram system includes a progressive gap between the first contact surface and the second contact surface larger at a first end than at a second end such that a first gap distance at the first end is greater than a second gap distance the second end.

An apparatus is disclosed as including a first material volume with at least a hardened portion and a second material volume that includes at least two layers. The first material volume is composed of at least a hardenable alloy of steel. The at least two layers is located adjacent to a first surface comprising the hardened portion of the first material volume. The at least two layers includes a first layer composed of at least a ductile low-carbon alloy of steel and a second layer composed of at least a cobalt-based hardfacing over the first layer. The apparatus is applicable in preparing shear ram blocks and shear ram blades to provide a hardened blade edge with an adjacent hardfacing surface.

A subsea shutoff device, in particular for use in water depths of more than 30 m for operating a valve with a gate with a waterproof, oil filled housing, a crank mechanism arranged in the housing, and a rotary actuator, wherein the rotary actuator is adapted to operate a gate of a valve via the crank mechanism.

The invention provides a cutting valve comprising a valve block, a gate, which is slidably within a cavity in the valve block from an open position to a closing and cutting position, an upper seat arranged in an upper part of the valve between the valve block and the gate, and a lower seat arranged in a lower part of the valve between the valve block and the gate, The valve further comprises an upper resilient member arranged between the upper seat and a lower resilient member arranged between the valve block and the lower seat. The cutting valve being distinctive in that the combination of height of upper seat, and lower seat, resilient member and any spacers on the lower side of the gate is selected so that an allowed travelling distance for the upper seat towards the valve block and an allowed travelling distance for the lower seat towards the valve block, are substantially equal.

A Compact Bonnet Booster (CBB) housing is monolithically formed to include an operating piston chamber, a booster piston chamber and two BOP bonnet end caps. When the CBB is assembled, the two BOP bonnet end caps contain bonnet hydraulic assemblies utilized to open and close the CBB housing with respect to a central BOP housing interior to change out the shear members. The CBB housing also defines therein hydraulic lines to open and close the wellbore utilizing the shear members as well as to operate the bonnet hydraulic assemblies. The CBB housing also incorporates a lifting pad eye near a center of gravity of said BOP. The CBB assembly also comprises a monolithically formed operating piston and corresponding shaft as well as a monolithically formed booster piston and corresponding shaft.