This disclosure includes auxiliary-line riser segment assemblies (e.g., with isolation units) that are suitable for managed pressure drilling (MPD) and that can be lowered (e.g., when connected to other riser segment assemblies) through a rotary of a drilling rig. Some embodiments are configured to have portions of the auxiliary lines connected (e.g., without welding) below the rotary.

A drilling marine riser section comprises a main riser pipe with radially extending flanges and multiple auxiliary pipes at least comprising a choke line and a kill line. One or more clamps retain the auxiliary pipes. Further the riser section has buoyancy members. The choke line and the kill line are connected to each of the flanges in a tensile load sharing arrangement, so that—in vertical use orientation of the riser section in a riser string—weight stress is distributed in the main riser pipe and the choke line and the kill line. The buoyancy members form an exterior of the riser section including diametrically opposed and parallel flat bottom and top stacking faces relative to the axis of the main riser pipe, allowing stacking of riser sections in horizontal orientation. The choke line and the kill line are arranged diametrically opposite from one another and between the flat bottom and top stacking faces.

A riser system configured to be secured between a surface vessel and a subsea location comprises a primary conduit and an auxiliary conduit extending adjacent the primary conduit, wherein the primary and auxiliary conduits are connected together at an axial location along the riser system via a connecting portion. The auxiliary conduit comprises a composite material formed of at least a matrix and one or more reinforcing elements embedded within the matrix.

A riser fluid handling system for managed pressure drilling includes a tubular portion having a lower end configured to be connected to a riser and an upper end, a spool connected to the upper end of the tubular portion, the spool having a base and a fluid conduit extending radially outward from the base and defining an axially-facing orifice. The fluid conduit is configured to provide fluid communication between the orifice and an interior of the spool. The system includes a valve connected to the fluid conduit and extending parallel to a central longitudinal axis of the tubular portion, the valve being configured to connect to a drape hose such that the drape hose extends axially therefrom and is able to swivel with respect to the spool.

An integrated managed pressure drilling (“MPD”) riser joint includes an annular sealing system that allows for the installation, engagement, service, maintenance, disengagement, removal, or replacement of one or more sealing elements while maintaining a pressure tight seal on the annulus without a drill string isolation tool, or equivalent thereof. The integrated MPD riser joint is limited to the annular sealing system and a flow spool, or equivalent thereof, disposed directly below the annular sealing system, without any intervening pressure containment devices or systems. Advantageously, the integrated MPD riser joint does not require a drill string isolation tool, or equivalent thereof, and may be substantially shorter in length and weigh substantially less than a conventional integrated MPD riser joint. The reduction in size and weight enables adoption of MPD technology in applications where conventional integrated MPD riser joints are not economically feasible or are otherwise precluded from use.

A riser assembly includes a riser with a first and second riser joint, an auxiliary line, and a first and second flange. The auxiliary line has an auxiliary line joint which connects a first and second auxiliary line section. The auxiliary line joint has a first joint assembly connected to the first auxiliary line section, and a second joint assembly connected to the second auxiliary line section. The first and second joint assembly each have a bearing surface. A bearing surface of the first flange engages the bearing surface of the first joint assembly. A bearing surface of the second flange engages the bearing surface of the second joint assembly. The bearing surface of the first flange or of the first joint assembly also has a rocker formation which contacts the bearing surfaces of the first flange and of the first joint assembly while permitting a relative angular movement therebetween.

An auxiliary line system for a drilling riser includes a first auxiliary line portion configured to couple to a first section of the drilling riser, a second auxiliary line portion configured to couple to a second section of the drilling riser, and a breech lock connection. The breech lock connection includes a first portion configured to couple to the first auxiliary line portion and comprising a first engagement feature and a second portion configured to couple to the second auxiliary line portion and comprising a second engagement feature. The breech lock connection is configured to adjust between a locked configuration and an unlocked configuration.

Blowout preventers having bodies with internal choke and kill line pass-through conduits are provided. In one embodiment, a blowout preventer body (42) includes a drill-through bore (44) extending through the blowout preventer body and a ram cavity (58) transverse to the drill-through bore. The blowout preventer body can also include choke and kill line conduits (136, 138) extending through the blowout preventer body, as well as choke and kill line access branch conduits (148, 150) extending between the choke and kill line conduits and the drill-through bore. Additional systems, devices, and methods are also disclosed.

An auxiliary line system for a drilling riser includes a first auxiliary line portion configured to couple to a first section of the drilling riser, a second auxiliary line portion configured to couple to a second section of the drilling riser, and a breech lock connection. The breech lock connection includes a first portion configured to couple to the first auxiliary line portion and comprising a first engagement feature and a second portion configured to couple to the second auxiliary line portion and comprising a second engagement feature. The breech lock connection is configured to adjust between a locked configuration and an unlocked configuration.

Systems and methods for control/monitoring of internal equipment in a riser assembly are disclosed. The method includes running a tool through at least a portion of an internal bore of a riser assembly associated with a well, and outputting a control signal from a first wireless communication interface disposed along the internal bore of the riser assembly. The first wireless communication interface is coupled to a communication system on the riser assembly. The method also includes receiving the control signal at a second wireless communication interface disposed on the tool, and actuating at least one equipment component of the tool in response to the second wireless communication interface receiving the control signal.