LASER MANDREL FOR REMOVAL OF SCALE IN PRODUCTION EQUIPMENT

Abstract

The present invention presents a laser mandrel (9) capable of being installed in the production string, in a position below the ICVs valves (2 and 4), to be used in a first moment aiming at preventing the formation of scale in the ICVs valves (2 and 4), and, in a second moment, for the removal of scale from the production string (1).

The laser mandrel (9) of this invention is provided with fiber optic cable (5), electrical cable (6), collimators (7), and laser diodes (8). It can be applied to prevent damage to well strings with electric intelligent completion, in case there is a failure in the chemical injection system installed in the string. It also makes possible the improvement of the technique aiming at the inhibition of inorganic depositions. Furthermore, it has a significantly lower cost than the conventional squeeze and/or removal, because once it is installed in the string, it allows the management of scale.

Claims

1. A LASER MANDREL FOR REMOVAL OF SCALE IN PRODUCTION EQUIPMENT, characterized in that it comprises fiber optic cable (5), electrical cable (6), collimators (7), and laser diodes (8).

2. THE LASER MANDREL FOR REMOVAL OF SCALE IN PRODUCTION EQUIPMENT according to claim 1, characterized in that it is installed in the production string (1), in a position just below the electric intelligent completion valves (2 and 4), with the mandrel (9) coupled to the electrical cable (6) of the intelligent completion.

3. THE LASER MANDREL FOR REMOVAL OF SCALE IN PRODUCTION EQUIPMENT according to claim 1, characterized in that the mandrel (9) is periodically driven to prevent scale inside the valves (2 and 4), inside the production string (1).

4. THE LASER MANDREL FOR REMOVAL OF SCALE IN PRODUCTION EQUIPMENT according to claim 1, characterized in that the mandrel (9) is driven to heat scale remover solutions inside the valves (2 and 4) and in the production string (1).

Description

BRIEF DESCRIPTION OF DRAWINGS

[0013] The present invention will be described in more detail below, with reference to the attached figures which, in a schematic form and not limiting the inventive scope, represent examples of its embodiment. In the drawings, there are:

[0014] FIG. 1 illustrating a well provided with intelligent completion for two producing intervals, where they are represented: PS (1), upper ICV (2), packer (3), lower ICV (4);

[0015] FIG. 2 illustrating the formation of scales inside the PS and through the holes of the ICVs, where there are represented: PS (1), upper ICV (2), packer (3), lower ICV (4), side view of the formation of the scale ring on the inside of the PS (a), top view of the formation of the scale ring on the inside of the PS (b), detail of the beginning of scale formation in the holes of the ICVs valves (c);

[0016] FIG. 3 illustrating the growth of scale inside the PS and through the holes of the ICVs, where the following are represented: PS (1), upper ICV (2), packer (3), lower ICV (4), side view of the increase of the thickness of the scale ring on the inside of the PS (d), top view of the increase in the thickness of the scale ring on the inside of the PS (e), detail of the growth of scale from the holes of the ICV valves to the inside of the PS (f);

[0017] FIG. 4 illustrating the gradual blockage by scale in ICVs;

[0018] FIG. 5 illustrating the schematic of the laser mandrel tool, object of this invention, where there are represented: PS (1), fiber optic cable (5), electrical cable (6), collimators (7), laser diodes (8), laser mandrel (9);

[0019] FIG. 6 illustrating the positioning of the laser mandrel in the production string, where the equipment is installed below the ICVs;

[0020] FIG. 7 illustrating the laser mandrel in a first option, to prevent scale;

[0021] FIG. 8 illustrating the laser mandrel in a second option, for scale removal.

DETAILED DESCRIPTION OF THE INVENTION

[0022] There follows below a detailed description of a preferred embodiment of the present invention, by way of example and in no way limiting. Nevertheless, there will be clear to a technician skilled in the art, from reading this description, possible further embodiments of the present invention still encompassed by the essential and optional features below.

[0023] The equipment of the invention may serve as a previous option to avoid the accumulation of scaling material, such as calcium carbonate, inside the production string of the wells, thus maintaining cleanliness, avoiding the need to apply conventional processes, such as the squeeze operation in the reservoir, and/or removal of scale in the production system equipment.

[0024] The equipment can be installed in the well construction phase, in the completion step. In operations to fight the loss of circulation in the well, the invention has the technical advantage of taking advantage of the completion fluid that the well will absorb to perform a previous inhibition of the reservoir, thus using the porous spaces of the reservoir rock to reserve inhibited completion fluid, which will thus be available inside the reservoir, when the well is producing.

[0025] The laser mandrel of this invention (9) will be mounted on the PS (1) in a position just below the electric intelligent completion valves (2 and 4) and will be coupled to the electrical cable (6) of the intelligent completion. The equipment (9) will consist of laser diodes (8), which generate the laser radiation, fiber optic cables (5) to conduct the laser energy, and collimators (7), which are responsible for projecting the laser beam inside the string (1).

[0026] The technology may be integrally applied in the management of scale in the wells and in ensuring the flow of production from the wells. It may further be applied as part of the technology used in the construction of wells in the completion phase.

[0027] The equipment will be installed in the PS (1) in a position designed to achieve the objective of dissolving the scales before they form a large amount of precipitate inside, mainly in the vicinity of the electrical ICVs (2 and 4).

[0028] Tests carried out in the laboratory proved that the application of laser radiation to generate tunnels (perforations) in plugs of carbonate rocks caused the thermal disintegration of carbonate into carbon dioxide (CO.sub.2) and calcium oxide (CaO). Thus, the use of laser is applicable for the thermal dissolution of carbonate. Furthermore, reports of scale removal tests, by means of the application of heat to chelating solutions, demonstrated an increase in the reaction yield and, consequently, in the scale removal efficiency.

[0029] The laser mandrel of this invention shall be installed on the PS (1), in a position below the ICV valves (2 and 4), to be used, in a first moment, aiming at preventing the formation of scale on the ICV valves (2 and 4), and, in a second moment, for the removal of scale in the PS (1).

[0030] To prevent the formation of scale in the valve holes (2 and 4), the mandrel (9) shall be periodically activated, promoting the heating of the oil produced by the well, in order to create greater turbulence inside the valves, inside the string, helping in the process of disaggregation of the scale. The mandrel laser (9) must be activated in the scale direction, inside the production string and below the ICVs. This option is demonstrated in FIG. 7.

[0031] For the removal of the scale formed in the valves (2 and 4), the mandrel (9) shall be activated to heat the removal solutions. The laser mandrel (9) may help to increase the efficiency of remote treatments, because it will be able to heat the removal solutions that will be pumped by the SPU and/or stimulation boat into the PS (1) and positioned in front of the ICVs (2 and 4), inside the PS (1). In this case, the mandrel laser (9) shall be activated in the scale direction, inside the production string and below the ICVs (2 and 4), passing through the chelating remover solution. This option is demonstrated in FIG. 8.

[0032] As for the removal of scale in the PS (1) at points above the ICVs (2 and 4), the laser mandrel (9) may also help to increase the efficiency of remote treatments, by heating the removal solutions that will be pumped by the SPU and/or stimulation boat into the PS (1), in the region where the scale is positioned.