The invention relates to reamers used in downhole oil well drilling operations, particularly in reaming while drilling applications. Presented is a reamer having an interior channel which runs along an elongate axis of the entire body of the reamer, wherein there are openings along both ends of the reamer, exposing the interior channel. Additionally presented in the reamer are a plurality of paths extending parallel to the interior channel along the exterior of the body of the reamer, and running in a helical pattern along the entirety of the exterior of the body of the reamer. Disposed within the helical paths are a plurality of cutting inserts, which cutting inserts are enabled to provides a uniform cutting surface against a well bore, which preferably improves cutting action and reduces strain on the reamer.

Offshore drilling system for performing subsea wellbore related activities including a drilling vessel, with a floating hull subjected to heave motion. A main cable heave compensation sheave is provided for heave compensation of a travelling block. A connection cable heave compensation sheave is provided between a connection cable winch and a top sheave assembly supported on the hull of the vessel in or above the moonpool. The main cable heave compensation cable sheave and the connection cable heave compensation sheave are mechanically interconnected so as to allow for synchronous motion thereof.

Offshore drilling system for performing subsea wellbore related activities including a drilling vessel, with a floating hull subjected to heave motion. A main cable heave compensation sheave is provided for heave compensation of a travelling block. A connection cable heave compensation sheave is provided between a connection cable winch and a top sheave assembly supported on the hull of the vessel in or above the moonpool. The main cable heave compensation cable sheave and the connection cable heave compensation sheave are mechanically interconnected so as to allow for synchronous motion thereof.

A position manager may receive time-based block position data of a travelling block above a drill floor on a floating drill rig, wherein the time-based block position data is received from a block position sensor on the drill floor. A position manager may apply a changepoint model to the time-based block position data to separate the time-based block position data into a plurality of segments. A position manager may determine a best segment of the plurality of segments. A position manager may generate a de-sensitized block position using the best segment of the plurality of segments.

A position manager may receive time-based block position data of a travelling block above a drill floor on a floating drill rig, wherein the time-based block position data is received from a block position sensor on the drill floor. A position manager may apply a changepoint model to the time-based block position data to separate the time-based block position data into a plurality of segments. A position manager may determine a best segment of the plurality of segments. A position manager may generate a de-sensitized block position using the best segment of the plurality of segments.

A land based dynamic sea motion simulating test drilling rig has a soil bound foundation and a pivot structure secured to said foundation. A motion base is mounted on said pivot structure and pivotable about at least one horizontal pivot axis. A drilling tower is erected on said motion base and is provided with a hoisting device adapted to manipulate a drill string section in a vertical firing line. A drilling tubulars storage vertically stores drilling tubulars and a tubulars racker device moves drilling tubulars between the drilling tubulars storage device and the firing line allowing for assembly and disassembly of a drill string section in the firing line. A motion drive is provided which is adapted to impart cyclic pivoting motion about said at least one horizontal pivot axis to the assembly of the drilling tower, drilling tubulars storage, and tubulars racker device in order to simulate said assembly being subjected to a sea state induced motion.

A land based dynamic sea motion simulating test drilling rig has a soil bound foundation and a pivot structure secured to said foundation. A motion base is mounted on said pivot structure and pivotable about at least one horizontal pivot axis. A drilling tower is erected on said motion base and is provided with a hoisting device adapted to manipulate a drill string section in a vertical firing line. A drilling tubulars storage vertically stores drilling tubulars and a tubulars racker device moves drilling tubulars between the drilling tubulars storage device and the firing line allowing for assembly and disassembly of a drill string section in the firing line. A motion drive is provided which is adapted to impart cyclic pivoting motion about said at least one horizontal pivot axis to the assembly of the drilling tower, drilling tubulars storage, and tubulars racker device in order to simulate said assembly being subjected to a sea state induced motion.

The present invention relates to a method for riser string handling on an offshore drilling vessel (1), the offshore drilling vessel comprising a multiple firing line hoist system, a riser tensioner system (50) arranged in the second firing line, and a suspended riser transfer device (60). The method comprising the steps of lowering a riser string in the first firing line, and simultaneously assembling and preparing a riser tensioner system in the second firing line, wherein the riser hang-off assembly displaces the riser string, leaving the top end of the riser string exposed, from the first firing line to the second firing line to be connected to the riser tensioner system.

The present invention relates to a method for riser string handling on an offshore drilling vessel (1), the offshore drilling vessel comprising a multiple firing line hoist system, a riser tensioner system (50) arranged in the second firing line, and a suspended riser transfer device (60). The method comprising the steps of lowering a riser string in the first firing line, and simultaneously assembling and preparing a riser tensioner system in the second firing line, wherein the riser hang-off assembly displaces the riser string, leaving the top end of the riser string exposed, from the first firing line to the second firing line to be connected to the riser tensioner system.

An offshore drilling vessel includes a main deck, a moonpool a firing line hoist system having a tower, a BOP transport system and a pivotally supported U-shaped working deck. The U-shaped working deck can be pivoted between an active position, in which it extends in a substantially horizontal direction such that it covers a portion of the moonpool, and a non-active position, in which it extends in a substantially vertical direction such that it provides room for a BOP to be moved by the BOP transport system from a storage position adjacent the moonpool into a launch position above the moonpool, in which launch position the BOP is located between the tower and the working deck.