A method includes disposing a device into a borehole in proximity to a subterranean formation where a filter cake has been formed adjacent thereto, the device comprising a support structure and a shape-memory article disposed at the support structure, the shape-memory article comprising a shape-memory polymer, wherein the device is disposed when the shape-memory article is in a compacted shape; exposing the shape-memory article to a fluid system to cause the shape-memory article to expand and conform to a surface of the borehole; exposing the filter cake to the fluid system; and removing the filter cake with the fluid system. The fluid system comprises (i) an acid component, a chelating agent, or a combination thereof; (ii) an activator, (iii) a viscosifier, (iv) water or a brine, and (v) optionally a surfactant.

A method includes disposing a device into a borehole in proximity to a subterranean formation where a filter cake has been formed adjacent thereto, the device comprising a support structure and a shape-memory article disposed at the support structure, the shape-memory article comprising a shape-memory polymer, wherein the device is disposed when the shape-memory article is in a compacted shape; exposing the shape-memory article to a fluid system to cause the shape-memory article to expand and conform to a surface of the borehole; exposing the filter cake to the fluid system; and removing the filter cake with the fluid system. The fluid system comprises (i) an acid component, a chelating agent, or a combination thereof; (ii) an activator, (iii) a viscosifier, (iv) water or a brine, and (v) optionally a surfactant.

A method of removing dope from a tubing system in a wellbore includes the step of, prior to setting a production packer, reverse circulating fluid within a tubing-casing annulus (TCA) so that is flows from the tubing-casing annulus into a first tubing and propels at least one wiper plug within the first tubing in an uphole direction, thereby wiping the inside of the first tubing and removing excess dope.

A method of clearing well casing (3) or tubing from a target region of an oil/gas well (1) borehole is provided. The clearance of the oil/gas well bore hole being achieved by employing chemical agents (9) that consume, weaken or melt the well casing/tubing. In some aspects of the method the well casing is cleared to expose the rock formation within which the well borehole is formed so that the rock formation can be accessed from within the well casing/tubing. In other aspects of the method the removal of inner tubing structures is used to facilitate the unimpaired deployment of repair tools down the well borehole.

A method of clearing well casing (3) or tubing from a target region of an oil/gas well (1) borehole is provided. The clearance of the oil/gas well bore hole being achieved by employing chemical agents (9) that consume, weaken or melt the well casing/tubing. In some aspects of the method the well casing is cleared to expose the rock formation within which the well borehole is formed so that the rock formation can be accessed from within the well casing/tubing. In other aspects of the method the removal of inner tubing structures is used to facilitate the unimpaired deployment of repair tools down the well borehole.

A tubular jetting device includes at least one inlet port that includes a first inlet opening in an inner surface of the tubular jetting device where the inner surface defines a center bore. The at least one inlet port also includes a second inlet opening in an end surface of the tubular jetting device and an inlet channel extending between the first inlet opening and the second inlet opening. The tubular jetting device further includes at least one exhaust port that includes a first exhaust opening in the end surface, a second exhaust opening in an outer surface of the tubular jetting device, and an exhaust channel extending between the first exhaust opening and the second exhaust opening.

A tubular jetting device includes at least one inlet port that includes a first inlet opening in an inner surface of the tubular jetting device where the inner surface defines a center bore. The at least one inlet port also includes a second inlet opening in an end surface of the tubular jetting device and an inlet channel extending between the first inlet opening and the second inlet opening. The tubular jetting device further includes at least one exhaust port that includes a first exhaust opening in the end surface, a second exhaust opening in an outer surface of the tubular jetting device, and an exhaust channel extending between the first exhaust opening and the second exhaust opening.

The present invention addresses to a system for removing hydrates and other scales in subsea pipes in oil production fields. More specifically, the present invention addresses to a system for fighting and removing hydrates and other scales comprising independent traction modules, equipped with load cells that act by controlling other traction modules, wherein said traction modules are interconnected intercalated with armored cable sections. The system of the present invention is applied in rigid or flexible pipes that present restrictions or blocks to the flow.

The present invention addresses to a system for removing hydrates and other scales in subsea pipes in oil production fields. More specifically, the present invention addresses to a system for fighting and removing hydrates and other scales comprising independent traction modules, equipped with load cells that act by controlling other traction modules, wherein said traction modules are interconnected intercalated with armored cable sections. The system of the present invention is applied in rigid or flexible pipes that present restrictions or blocks to the flow.

Various embodiments provide methods and systems for providing fluid lighteners for use in downhole wells. The fluid lighteners may include one or more viscosifiers, one or more aphron generators, and a location-specific non-emulsifying surfactant.