An ultra-high pressure (UHP) cutting device for cutting an elongate body from outside the elongate body are disclosed herein. Embodiments of the UHP cutting device have a UHP tube with a top end and a bottom end opposite the top end, the UHP tube defining a lumen for receiving UHP fluid, a static mount for securing the cutting device to the elongate body, a rotatable mount rotatably connected to the static mount, a radially adjustable support member for adjusting a distance of the UHP tube to the elongate body, the radially adjustable support member being connected adjacent to the top end of the UHP tube and the rotatable mount, a drive in operational communication with the rotatable mount for rotating the rotatable mount during operation of the cutting device, and a cutter head in fluid communication with the UHP line. Related uses and methods are also disclosed herein.

An ultra-high pressure (UHP) cutting device for cutting an elongate body from outside the elongate body are disclosed herein. Embodiments of the UHP cutting device have a UHP tube with a top end and a bottom end opposite the top end, the UHP tube defining a lumen for receiving UHP fluid, a static mount for securing the cutting device to the elongate body, a rotatable mount rotatably connected to the static mount, a radially adjustable support member for adjusting a distance of the UHP tube to the elongate body, the radially adjustable support member being connected adjacent to the top end of the UHP tube and the rotatable mount, a drive in operational communication with the rotatable mount for rotating the rotatable mount during operation of the cutting device, and a cutter head in fluid communication with the UHP line. Related uses and methods are also disclosed herein.

An assembly to cut a hollow piling has a pressurized hydraulic fluid supply force to cut through a piling; a housing having a cavity to receive the hydraulic fluid, the housing having at least one cylinder wall; at least one piston assembly slidably disposed within the at least one cylinder wall configured to extend from the at least one cylinder wall in response to the introduction of pressurized hydraulic fluid into the housing cavity; a blade attached at a radially distal end of the piston assembly, whereby as the blade extends, a cutting force is applied to an encountered piling wall; wherein the blade edges are stepped/shingled on the upper and lower surface to allow overlapping of the blades when the blades are retracted. Spacers extend to a diameter equal to or beyond a blade tip diameter in its retracted position; and wherein the blade has a piercing point.

An assembly to cut a hollow piling has a pressurized hydraulic fluid supply force to cut through a piling; a housing having a cavity to receive the hydraulic fluid, the housing having at least one cylinder wall; at least one piston assembly slidably disposed within the at least one cylinder wall configured to extend from the at least one cylinder wall in response to the introduction of pressurized hydraulic fluid into the housing cavity; a blade attached at a radially distal end of the piston assembly, whereby as the blade extends, a cutting force is applied to an encountered piling wall; wherein the blade edges are stepped/shingled on the upper and lower surface to allow overlapping of the blades when the blades are retracted. Spacers extend to a diameter equal to or beyond a blade tip diameter in its retracted position; and wherein the blade has a piercing point.

A kit is disclosed for cutting differing sized pipes internally. The kit includes a pipe cutting apparatus, and a plurality of assemblies. The pipe cutting apparatus includes at least one drive member. The plurality of assemblies, attachable to the pipe cutting apparatus, each include: (1) at least one feed member to extend at least one cutting member against a pipe internally and to retract the at least one cutting member from the pipe internally, the at least one drive member to rotate the at least one cutting member against the pipe internally; or (2) at least one clamping member to secure the pipe cutting apparatus to the pipe internally. Each of the plurality of assemblies differ in size so that differing sized pipes can be cut internally by the pipe cutting apparatus by attaching the appropriately sized assembly to the pipe cutting apparatus.

A kit is disclosed for cutting differing sized pipes internally. The kit includes a pipe cutting apparatus, and a plurality of assemblies. The pipe cutting apparatus includes at least one drive member. The plurality of assemblies, attachable to the pipe cutting apparatus, each include: (1) at least one feed member to extend at least one cutting member against a pipe internally and to retract the at least one cutting member from the pipe internally, the at least one drive member to rotate the at least one cutting member against the pipe internally; or (2) at least one clamping member to secure the pipe cutting apparatus to the pipe internally. Each of the plurality of assemblies differ in size so that differing sized pipes can be cut internally by the pipe cutting apparatus by attaching the appropriately sized assembly to the pipe cutting apparatus.

Disclosed herein is a rotational roller apparatus for use with a pipeline unit. The pipeline unit is received in a pipeline for welding and/or inspection. The rotational roller is attached to and is able to support at least a portion of the weight of the pipeline unit. The rotational roller unit also includes an extension member and a reduced friction base. The reduced friction base is attached to an end of the extension member so that the rotational roller has a retracted and an extended configuration. In the extended configuration, the reduced friction base contacts an interior of the pipeline and supports at least a portion of the weight of the pipeline unit and thereby allows the unit to be rotated about a longitudinal axis within the pipeline.

A cutting device for cutting an optical fiber running in a first direction includes a supporting piece having a free end and a fixed end and having resilience, a cutting blade supported by the supporting piece that comes into contact with the optical fiber to make a right angle with the optical fiber at a point of the contact, and a driving device. The driving device is configured to press the supporting piece in a second direction in a plane perpendicular to the first direction, with the second direction not intersecting with the first direction.

The present disclosure provides an apparatus for removing material from an internal surface of a pipe. The apparatus comprises a low-power cutting tool for insertion into the pipe and configured to remove material from an internal surface of the pipe. The cutting tool comprises a housing for insertion within the pipe, a cutting head extending from the housing and a cutting tip for machining the internal surface of the pipe in a machining operation when the cutting tool is inserted into the pipe, and one or more actuators for driving the cutting tip. The apparatus further comprises one or more processors, and a computer-readable memory storing instructions which, when executed by the one or more processors, control the one or more actuators to cause the cutting tip to machine the internal surface of the pipe, such that the cutting tool is maintained in a low-power configuration.

A pipe cutting machine, which includes a hole-type movable cutting die (6b), which is driven by a drive lever (7), by means of which circular movements with a continuously variable stroke (h) can be performed, an eccentrically shaped crank pin bearing (26) in an outer shaft (18), in which a crank pin (11), which is arranged eccentrically on a crank pin drive (23), is movably supported in relation to the outer shaft (18), the crank pin (11) being in operative connection with the drive lever (7).