This application claims the benefit of priority from European Patent Application No. 15 305 193.3, filed on Feb. 10, 2015, the entirety of which is incorporated by reference.
The present invention relates to a rigid cable for downhole tractor deployment as defined in the preamble of claim 1 and a well system using such a power cable.
Vertical, inclined and horizontal drilling of boreholes plays an important role in the field of hydrocarbon production. Inclined and horizontal drilling is typically performed in order to recover oil from a plurality of nearby reservoirs, thereby avoiding the need of drilling a large number of vertical boreholes from the surface. In particular, it is often desirable to initially drill vertically downward to a predetermined depth, and then to drill at an inclined angle therefrom to reach a desired target location. This allows oil to be recovered from a plurality of nearby underground locations while minimizing drilling. In addition to oil recovery, boreholes with a horizontal component may also be used for a variety of other purposes such as coal exploration and the construction of pipelines and communication lines.
Two methods of drilling vertical, inclined and horizontal boreholes are rotary drilling and coiled tubing drilling.
In rotary drilling, a rigid drill string consisting of a series of connected segments of drill pipes is lowered from the around surface using surface equipment such as a derrick and draw works. Attached to the lower end of the drill string is a bottom hole assembly which may comprise a drill bit, drill collars, stabilizers, sensors and a steering device. A top drive system rotates the drill string, the bottom hole assembly and the drill bit, allowing the rotating drill bit to penetrate into the formation. The inclination of the rotary drilled borehole may be gradually altered by using known equipment such as a downhole motor with an adjustable bent housing to create inclined and horizontal boreholes.
In coiled tubing drilling, the drill string is a non-rigid, generally compliant tube. The tubing is fed into the borehole by an injector assembly at the ground surface. The coiled tubing drill string can have specially designed drill collars located proximate the drill bit that apply weight to the drill bit to penetrate the formation. The drill string is not rotated. Instead, a downhole motor provides rotation to the bit. Because the coiled tubing is not rotated, or not normally used to force the drill bit into the formation, the strength and stiffness of the coiled tubing is typically much less than that of the drill pipe used in comparable rotary drilling. Thus, the thickness of the coiled tubing is generally less than the drill pipe thickness used in rotary drilling, and the coiled tubing generally cannot withstand the same rotational, compression and tension forces compared to the drill pipe used in rotary drilling.
In both rotary and coiled tubing drilling, downhole tractors are used to apply axial loads to the drill bit, bottom hole assembly and drill string, and generally to move the entire drilling apparatus into and out of the borehole. The tractor may be designed to be secured at the lower end of the drill string. The tractor may have anchors or grippers adapted to grip the borehole wall just proximal the drill bit. When the anchors are gripping the borehole, hydraulic power from the drilling fluid may be used to axially force the drill bit into the formation. The anchors may advantageously be slidably engaged with the tractor body so that the drill bit, body and drill string can move axially into the formation while the anchors are gripping the borehole wall.
There exist numerous ways to achieve the above mentioned axial movement of the downhole tractors into the formation, Examples of different propulsion solutions may be found in patent publication U.S. Pat. No. 6,003,606 and CA 2'686'627 A1. However, a common need for all prior art solutions is the presence of adapted wireline cables extending from the ground surface sea level to the downhole tractors. The application of such cables may be challenging. One problem associated with the above mentioned tractoring operations is abrasion and/or cutting of the cables from the borehole casings, thereby causing cable damage and/or blockage. These problems increase with the length and/or degree of deviation of the borehole. Furthermore, the latter contributes to an increase friction between the outside surface of the cable and the borehole walls. In order to overcome the above mentioned problems it is common to surround the conducting core of the cable with a thick metallic armour sheath, which typically constitutes a coverage of 98% of the cable cross section. Examples of cables with such a metallic armour sheath may be found disclosed in patent publication WO 2011/037974, WO 03/091782 A1 and WO 97/30369 A1.
However, an additional problem with high weights and significant frictions during movements in inclined and/or horizontal boreholes is the need of increased motive power to the downhole tractors/tools. And an increase in power through the cable may require an increase in the conducting cross section of the cable, which again results in an increase in weight and/or friction.
There exist solutions were the cable itself is used to push the downhole tool along the borehole. This solution requires a cable having a high level of rigidity in order to enable the necessary pushing power to the downhole tool without risking significant cable buckling. The necessary rigidity has been achieved by covering the core copper conductors with a pure graphite sheath. However, this prior art solution has proved to be expensive and difficult to manufacture.
It is thus an object of the present invention to provide a power cable that both provides power to, and facilitates the movements of, downhole tractors/tools situated within boreholes. Another object of the present invention is to provide power cables that is easy to manufacture and which may accommodate larger power transmission compared to prior art solutions
The present invention is set forth and characterized in the main claim, while the dependent claims describe other characteristics of the invention.
In particular, the invention concerns a power cable suitable for providing power to and from a downhole tool situated within a borehole. The cable comprises at least one inner conductor comprising at least one first electrically conductive material, at least one inner insulating layer surrounding the inner conductor(s), comprising at least one electrically insulating material, an unmoor sheath surrounding the inner insulating layer(s) comprising at least one second electrically conductive material and at least one outer conducting layer surrounding, and electrically contacting, the armour sheath, comprising at least one third electrically conductive material. The armour sheath further comprises at least one inner radial layer comprising a plurality of armouring wires with a diameter D and at least one outer radial layer electrically contacting the inner radial layer(s), the outer radial layer(s) comprising a plurality of armouring wires (6c) with a diameter d, the diameter d being dissimilar to the diameter D, and wherein said armouring wires are radially arranged, in a closed packed structure in order to maximize the armour sheath density.
Hereinafter dissimilar diameters signifies mutual differences in wire diameters of more than 10%, more preferably more than 20%, for example 30%. Furthermore, conductive material signifies any material or combination of materials (e.g. mixture/alloys) that exhibits conductivity per unit length (σ) of more than 1×104 S/m at 20° C. (293 K) along at least part of the power cable, preferably along the whole length of the power cable. The conductivity per unit length of the first and third conductivity materials is preferably more than 1×106 S/m at 20° C., for example more than 1×107 S/m, at 20° C.
In one aspect of the power cable the inner conductor is a solid conductor. In this aspect the solid conductor avoids the risk of gas migration along the multiple wires of a stranded conductor.
In an advantageous embodiment the diameter D is larger than the diameter d.
In another advantageous embodiment the outer radial layer further comprises a plurality of armouring wires with diameter D′ arranged at least partly between the armouring wires with the diameter d and at least partly between the armouring wires with the diameter D of the inner radial layer, wherein the diameter D′ is larger than the diameter d, for example equal to diameter D.
In another advantageous embodiment the radially outermost surface positions of the armouring wires defining the outer radial periphery of the armour sheath constitute positions on a circle.
In another advantageous embodiment the second electrically conductive material(s) has/have higher tensile strength than at least one of the first and third electrically conductive material(s).
In another advantageous embodiment at least one of the first electrically conductive material(s) is identical to at least one of the third electrically conductive material(s).
In another advantageous embodiment at least one of the first and third conductive material(s) comprises mainly copper or a copper alloy.
In another advantageous embodiment the conductivity per unit length at 20° C. of the first and third electrically conductive material(s) is higher than the conductivity per unit length at 20° C. of the second electrically conductive material(s).
In another advantageous embodiment the second electrically conductive material(s) comprises mainly steel.
In another advantageous embodiment at least the majority of interstices within the armour sheath are filled with a pressure compensating filling material comprising an elastic material, for example a petroleum jelly.
In another advantageous embodiment at least one outer insulating layer surrounds the outer conducting layer(s), wherein the outer insulating layer(s) is/are preferably made of a fluorine based polymer such as a fluorine based polymer within the group poly/ethane-co-tetrafluoroethene (ETFE), fluorinated ethylene propylene (FEP), perfluoroethers (PFA), ethylene-fluorinated ethylene propylene (EFEP), or a combination thereof.
The invention also concerns a downhole tool assembly for drilling a borehole for hydrocarbon production, comprising at least one downhole tool and at least one power cable in accordance with any of the above mentioned embodiments which is/are in one longitudinal end electrically connected to the downhole tool.
In the following description, specific details are introduced to provide a thorough understanding of an embodiment of the claimed power cable. One skilled in the relevant art, however, will recognize that this embodiment can be practiced without one or more of the specific details, or with other components, systems, etc. In other instances, well-known structures or operations are not shown, or are not described in detail, to avoid obscuring aspects of the disclosed embodiments.
A cross section of a power cable 1 in accordance with the invention is shown in
The above described configuration provides a power cable 2 having a main return conductor 7 compactly arranged within the cable's 1 cross section. This relatively simple cable design makes the production of power cables of long length (i.e. several kilometres) easier while allowing accommodation of a larger power transmission compared to prior art solutions.
The main purpose of the armour sheath 6 is to protect the inner insulated conductor(s) 2 and give the cable 1 high longitudinal strength, i.e. at strength that at least corresponds to a strength necessary for the cable 1 to carry its own weight. This is often a critical requirement for cables employed at large sea depths such as depths of more than four kilometres. For this reason the armour sheath 6 preferably exhibits higher tensile strength than both the inner core 2,3 and the tube 7. Relevant examples of conductive materials with high tensile strength may be various steel types, tungsten, titanium alloys and aluminium alloys, or a combination thereof. In the embodiment of
The armour sheath 6 and the tube 7 are preferably electrically connected along at least the major part of the cable's longitudinal length in order to maximise the radial cross section in which electrical power may flow during return from the downhole tool.
Note that the direction of the power flow may be interchanged as convenient. For example, in an alternative embodiment of the invention armour sheath 6 and/or the tube 7 may act as an conductor for the power flow into the downhole tool, in which case the one or more insulated conductors 2 of the inner core 2,3 act as the conductor for the power flow from the downhole tool,
Typical dimensions of the inventive power cable 1 are
The above mentioned radial arrangement is typically arranged in order to support a cable weight of at least 4 km sea depth, for example 5 km sea depth. The weight of the inventive power cable 1 may be within the range 0.4-0.8 kg/m, for example about 0.6 kg/m.
The power cable 1 may be used as part of a downhole tool arrangement such as a cable transmitting necessary power to a downhole tractor within a hydrocarbon producing well.
Power cable 1
Insulated conductor 2
Electrically insulating sheath 3
Interstices (between armour wires) 4
Armour sheath 6
Armouring wire with diameter D 6a
Armouring wire with diameter D′ 6b
Armouring wire with diameter d′ 6c
Inner radial layer 6′
Outer radial layer 6″
Conducting tube 7
Outer insulating layer 8
Number | Date | Country | Kind |
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15305193 | Feb 2015 | EP | regional |
Number | Name | Date | Kind |
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5787217 | Traut | Jul 1998 | A |
9627100 | Pourladian | Apr 2017 | B2 |
20120222869 | Varkey | Sep 2012 | A1 |
20150348677 | Pourladian | Dec 2015 | A1 |
Number | Date | Country |
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2014062061 | Apr 2014 | WO |
Entry |
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Search Report dated 2015. |
Number | Date | Country | |
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20160233008 A1 | Aug 2016 | US |