A dual telemetric coiled tubing running string for disposing a bottom hole assembly into a wellbore. The dual telemetric coiled tubing running string includes a string of coiled tubing which defines a flowbore along its length, an electrical wire conduit disposed within the flowbore, and an optic fiber disposed within the flowbore.

Implementations described and claimed herein provide systems and methods for extending reach in a wellbore in oil well operations. In one implementation, a first coiled tubing string has a first coil interior surface, and a second coiled tubing string is disposed within the first coiled tubing string and has a second coil exterior surface. An annulus is defined by the first coil interior surface and the second coil exterior surface. The annulus is sealed proximal to a top end of the first coiled tubing string via a first seal and sealed proximal to a bottom end of the first coiled tubing string via a second seal. A fluid is sealed within the annulus at a pressure.

The invention relates to long, flexible tubing which can be wound on a spool (coiled tubing or flexible production tubing), and comprises two closed channels combined in a single structure, said channels being formed from a single strip by repeated and successive shaping and welding, and being joined to one another by a connecting, jointing or dividing partition. A connecting partition is perforated, and has mounted thereon a flexible service belt having locking connecting cams which correspond to matching locking holes on the perforated connecting partition. The service belt has electrical cables, wires, capillary tubing, and fiber optic lines arranged therein, and the interval between the connecting cams is twice the size of the interval between the holes on the perforated connecting partition. If the closed channels are joined by an jointing partition, then a pipe-in-pipe design variant is used. If the closed channels are joined by a dividing partition, then the latter also forms part of the wall of both closed channels. The dividing partition can be twice the thickness of the strip. The weld seams, the centers of the closed channels and the partition are situated on a midline of a cross section of the string, parallel to the axis of a spool. The proposed invention makes it possible to significantly increase the potential of coiled tubing units and of the coiled tubing itself by virtue of being multi-channeled and, as a result, multi-functional.

The invention relates to lengthy umbilical flexible tubing that can be wound on a reel, and more particularly to coiled tubing or flexible production tubing. The technical effect is to increase the potential of well process operations. A lengthy umbilical flexible tubing element comprises at least two isolated channels combined to form a single structure. The isolated channels are joined to one another by an interfacing partition formed by welding the points of connection between the walls of the isolated channels to one another. The at least two isolated channels and the interfacing partition are formed from two separate metal strips by shaping said metal strips from the middle by longitudinal bending, and subsequently welding the opposing longitudinal edges of the two metal strips to one another. Jointing or dividing partition is provided with holes and is double the thickness of a metal strip. One of the metal strips is made of steel that exhibits high strength under tension, and the other metal strip is made of steel that exhibits high ductility under compression.

A connector secures an ESP to coiled tubing containing a power cable. Upper and lower barriers in the connector housing define an upper chamber, a lower chamber, and a center chamber. An upper chamber dielectric fluid in the upper chamber is in fluid communication with the interior of the coiled tubing. A lower chamber dielectric fluid in the lower chamber is in fluid communication with motor lubricant in the motor of the ESP. Center chamber dielectric fluid in the center chamber is sealed from contact with the upper and lower chamber dielectric fluids by the upper and lower barriers. A thermal expansion device has a container portion for allowing center chamber dielectric fluid to expand into the container.

A length of coiled tubing is installed into a horizontal side-track wellbore. The coiled tubing has a pre-perforated section that defines perforations between a first end of the perforated section and a second end of the perforated section. The perforated section is positioned to align with a zone of interest within the horizontal side-track wellbore. A first isolation packer surrounds the length of coiled tubing. The first isolation packer is attached to the length of coiled tubing at the first end of the pre-perforated section. A second isolation packer surrounds the length of coiled tubing. The second isolation packer is attached to the length of coiled tubing at the second end of the pre-perforated section.

Apparatus and methods for running casing into a wellbore. An apparatus may be or include a casing collar configured to couple together a first casing joint and a second casing joint. The casing collar may have a body and a plurality of rotatable members connected to the body. The body may have a fluid passage extending axially therethrough, a first coupler configured to couple the casing collar with the first casing joint, and a second coupler configured to couple the casing collar with the second casing joint. At least a portion of each rotatable member may extend from the body in a radially outward direction.

Methods and apparatuses are provided for clearing a wellbore using a component for milling and a component for suctioning within a wellbore. Obstructions such as ball frac seats, bridge plugs, or formation material can be milled within a wellbore. As a result, larger, unrestricted, diameters can be obtained within the liner/wellbore. The cleared wellbore can allow for various remedial tools to be run into the liner/wellbore. In addition, the milled particles can be suctioned/vacuumed up and can be pumped/pushed to surface in an underbalanced fashion. In some embodiments, this can be achieved by incorporating a bottom-hole pump or a venturi component into the bottomhole assembly. The system can be deployed using a spoolable single or multi-conduit coiled tubing system and can be configured as a well intervention or work-over technology. In some embodiments, the clearing equipment can be temporary or mobile.

A length of tubing and related apparatus and methods are described, where the length of tubing is deployable from a coiled configuration to an uncoiled configuration for performing a coiled tubing operation in a wellbore. The length of tubing includes a pipe of metal, and a liner of composite material that lines the pipe. The liner or the lined pipe includes a wall structure that incorporates means to communicate at least one service along the tubing.

A flat pack (1) for operating a downhole tool or sensor includes a plurality of tubes (3a, 3b); a spacer (2) disposed between the tubes (3a, 3b); and a jacket (4) encapsulating the tubes (3a, 3b) and the spacer (2). The tubes (3a, 3b) and the spacer (2) are positioned in the jacket (4) in a side-by-side arrangement. The tubes (3a, 3b) and the spacer (2) are not twisted along the flat pack (1).