A shear ram system includes an upper block coupled to a first arm, the upper block positioned to transition from a first location outside a bore to a second location within the bore, the upper block including an upper blade having a cutout formed at a radially outward end, the cutout having a cutout profile. The shear ram system also includes a lower block coupled to a second arm, the lower block positioned to transition from the first location outside the bore to the second location within the bore, the lower block including a gap control arm including a wear insert arranged axially higher than a lower blade, the gap control arm having an arm profile that substantially conforms to the cutout profile. The wear insert of the gap control arm is configured to engage the cutout when the upper block and the lower block are moved to the second location.

A blowout preventer (BOP) assembly includes a body portion, a bore extending through the body portion, and a ram block assembly. The ram block assembly includes a first ram block being movable into the bore and a second ram block being movable into the bore. The ram block assembly also includes inserts arranged within each of the first ram block and second ram block, the inserts being movable to change a sealing diameter of the ram block assembly, wherein each insert includes a plurality of lips extending into voids formed between adjacent inserts, respective lips being positioned along intersecting regions of adjacent inserts

A pressure control system includes a housing having a bore and a first pair of opposed rams positioned within the housing. The first pair of opposed rams is configured to move between a retracted position and an extended position relative to the bore. The pressure control system further includes a rotating control device (RCD) seal assembly, which includes a frame that is configured to couple to the first pair of opposed rams while the first pair of opposed rams are in the extended position relative to the bore, an annular seal element coupled to the frame, and a bearing assembly positioned between the annular seal element and the frame. The annular seal element is configured to seal about a tubular within the bore, and the bearing assembly is configured to enable the annular seal element to rotate relative to the frame and the first pair of opposed rams.

A blade includes a blade body extending a blade length and having a blade depth. The blade also includes a flat, arranged at a forward face, extending a flat length, less than the blade length. The blade further includes at least one slant, arranged at the forward face, the at least one slant being coupled to the flat and positioned at a slant angle, wherein the at least one slant includes a cutting edge.

A locking mechanism for a subsea cutting/sealing device to seal a wellbore and cut any drill pipe in the wellbore. The subsea cutting/sealing device locks two pipe cutters in a closed position utilizing locking mechanisms on two position rods. The position rods are part of a visual indicator that an ROV camera or diver may use to determine whether the pipe cutter is closed or open position. The locking mechanism operates according to a sequence of operation for opening/closing the pipe cutters. An ROV tool can be used that is capable of operating the locking mechanism as well as opening and closing the subsea cutting sealing device.

In some embodiments, a method for executing an emergency disconnect sequence in shallow water depth includes unlatching a lower marine riser package (LMRP) of a blowout preventer (BOP) from a lower stack of the BOP. The BOP defines a wellbore fluidically coupled to the subsea wellhead. A tubular is disposed within the wellbore. The method further includes shearing the tubular and sealing the wellbore. In response to an indication that a vessel operably coupled to the BOP has failed to keep station, an unlatch sequence and a shear and seal sequence are initiated, such that each sequence occurs at least partially simultaneously. The unlatch sequence includes disconnecting the LMRP from the lower stack, and the shear and seal sequence includes activating the lower stack to shear the tubular in less than about one second and seal the wellbore.

A subsea test tree assembly is provided which includes at least one subsea test tree or SSTT, the SSTT including a valve having at least one of a cutting function and a sealing function, the valve being movable between an open position and a closed position via hydraulic fluid supplied to the valve through control lines; and a control system including a source of hydraulic fluid, the control system being arranged to supply hydraulic fluid from the source of hydraulic fluid to the valve of the at least one SSTT on detecting that the control lines have been sheared, to automatically move the valve to the closed position. A method of controlling a well using an SSTT assembly is also provided.

A blowout preventer system including a lower blowout preventer stack comprising a number of hydraulic components, and a lower marine riser package comprising a first control pod and a second control pod adapted to provide, during use, redundant control of hydraulic components of the lower blowout preventer stack where the first and the second control pods are adapted to being connected, during use, to a surface control system and to be controlled, during use, by the surface control system. The blowout preventer system further including at least one additional control pod connected to at least one additional surface control system and to be controlled, during use, by the additional surface control system.

A wellbore control device comprising a housing (1) defining a throughbore (2) for receiving a tubular, a first gate (4) having a first hole (6) and a second gate (3) having a second hole (5), piston rods (12a,12b) operably connected to the first and second gates (4,5), the first and second gates (3,4) being supported by the housing (1) and movable transverse to the throughbore (2) between an open position and a closed position, wherein the open position the first and second holes (5,6) are aligned with the throughbore (2), and wherein the gates (3,4) in the closed position split an upper portion (2′) of the throughbore (2) completely from a lower portion (2″) of the throughbore (2).

The present disclosure relates to a system that includes a ram configured to mount in a blowout preventer. The ram includes a packer assembly configured to form a seal between the ram and a bore formed through the blowout preventer and an insert of the packer assembly, where the insert is coupled to a surface of the ram via a key-slot interface.