Method and Apparatus Suitable For Hole Cleaning During Operations

Abstract

Apparatus for drilling operations in underground boreholes, comprises: a drilling assembly that can be located in a borehole and is moved along the borehole during the drilling operation; a flexible fluid supply line connected to and in fluid communication with the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; and an electric cable for providing electric power to the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; the fluid line and the electric cable are separate, and the electric cable being outside the fluid line. A method for conducting drilling operations using an apparatus as defined above, comprises operating the drilling assembly and directing fluid between the surface and the drilling assembly via the flexible fluid line.

Description

TECHNICAL FIELD

The present invention relates to methods and apparatus for hole-cleaning applications that are particularly applicable to re entry and/or slim hole drilling with electrically powered and deployed drilling tools.

BACKGROUND ART

In conventional drilling, a drilling fluid performs the functions of transporting the drilled cuttings up to surface, ensuring well bore stability (by exerting enough hydrostatic pressure to support the well bore and retain formation fluids in place), cleaning and cooling of the drill bit, lubricating the bottom hole assembly (BHA), and allowing mud pulse telemetry (transmission of information from downhole measurement equipment to surface or vice-versa through pressure pulses). The displacement of cuttings is achieved by standard direct circulation: the drilling fluid is pumped from surface inside the drill string (either made of jointed rotating drill pipes or a length of continuous coiled tubing) and returns to the surface in the annulus between the drill string and the borehole wall where it carries the drilled cuttings in suspension up to surface. The drilled cuttings are then filtered out on surface and the drilling fluid is re-circulated inside the well. The combination of the drill string and surface pumps allows high flow rates to be obtained and therefore sufficient drilling fluid velocity for conveyance of drilled cuttings. The drill string (which serves as a flow conduit) also transmits weight to the drill bit to provide the axial drilling effort.

In certain situations, reverse circulation is used, in which drilling fluid is pumped down the well in the annulus and returns to the surface inside the drill string via the drill bit. This is not normally practical for situations in which the drilled cuttings have significant size.

Electric drilling aims to drill without the need for a rig or coiled tubing unit so there is often no drill string to circulate the drilling fluid. Additionally, as electric drilling is aimed at low power and low footprint systems, the traditional high power mud pumps are to be avoided. The drilling effort is electrically generated downhole so the flow conduit does not need to be able to transmit mechanical forces to the bit and can be more flexible and easier to handle on surface.

US 2004104052 A describes a directional drilling method using a concentric coiled tubing drill string connected to a directional bottom hole assembly. The system allows the drilling fluid and the drilled cuttings to be circulated through the concentric coiled tubing drill string, instead of through the annulus between the drill string and the borehole wall. Modified coiled tubing technologies and directional drilling tools are used to provide for reverse circulation of the drilling fluid, drilled cuttings and produced fluids.

U.S. Pat. No. 6,629,570 describes a downhole drilling method using electrically powered bottom hole assemblies in coiled tubing drilling applications. The system also uses direct or reverse circulation of the drilling fluid inside the coiled tubing, through the bottom hole assembly, through the bit and in the well annulus.

U.S. Pat. No. 6,323,420 describes a method and apparatus for providing cabling or an electrically conductive path in tubing. A cable or conductive member is housed securely between the outer surface of an inner tube and the inner surface of an outer coiled tubing.

PCT/WO 204072437 describes a directional drilling method and apparatus in which the bottom hole assembly is electrically powered and deployed in the well with a wireline cable. The system can also perform logging, completion and well instrumentation applications. A bag is used to collect drilled cuttings downhole.

DISCLOSURE OF THE INVENTION

The present invention is based on the use of separate fluid lines and electric cables that allows easy handling on surface.

One aspect of the invention provides an apparatus for drilling operations in underground boreholes, comprising: a drilling assembly that can be located in a borehole and is moved along the borehole during the drilling operation; a flexible fluid supply line connected to and in fluid communication with the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; and an electric cable for providing electric power to the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; characterised in that

the fluid line and the electric cable are separate, the electric cable being outside the fluid line.

The fluid line and the electric cable can be connected to each other in at least one location between the drilling assembly and the surface.

At least one drum can be included for storing and delivering the fluid line and/or cable to the well. Preferably separate drums are provided for the fluid line and electric cable.

The fluid line and/or the electric cable can be formed from segments joined end-to-end by connectors. In this case, a secondary fluid line can be connected to the fluid line in an upper region thereof, preferably at the connector between the uppermost segment and the adjacent segment.

A pressure-controlled housing can be provided in which the drum of the fluid line or the secondary fluid line can be located. The housing may also include a port to allow fluid to be introduced to or withdrawn from the fluid line or secondary fluid line.

Another aspect of the invention comprises a method for conducting drilling operations using an apparatus as defined above, the method comprising operating the drilling assembly and directing fluid between the surface and the drilling assembly via the flexible fluid line.

Preferably, the fluid is a drilling fluid which is introduced to the borehole at the surface and circulates from the bottom of the borehole back to the surface via the fluid line so as to carry drilled cuttings away from the drilling assembly.

The fluid line and the electric cable are fed into or withdrawn from the borehole as the drilling assembly moves along the borehole. The fluid line and electric cable can be connected together at various points along their length as they are fed into the borehole.

Where the fluid line and/or electric cable are formed from segments, the method can comprises joining the segments with connectors as the fluid line and/or electric cable are fed into the well, or disconnecting the segments at the connectors as the fluid line and/or electric cable are withdrawn from the well.

In one preferred embodiment, the method includes connecting a secondary fluid line to the fluid line in an upper region thereof, preferably between the uppermost segment and the adjacent segment. In such a case, the secondary fluid line is used to introduce or withdraw fluid from the fluid line. The secondary fluid line is typically shorter than the fluid line such that in use, the secondary fluid line is periodically disconnected from the fluid line and reconnected at another location as the fluid line is fed into or withdrawn from the borehole.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings,

FIG. 1 shows apparatus according to one embodiment of the invention;

FIG. 2 shows apparatus according to a second embodiment of the invention;

FIG. 3 shows a schematic view of an embodiment of an umbilical cable for use in the present invention;

FIGS. 4A and B show the manner in which a secondary fluid line is connected to a segmented fluid line; and

FIG. 5 shows apparatus using an umbilical cable and separate fluid line and electric cable.

MODE(S) FOR CARRYING OUT THE INVENTION

The present invention provides methods and apparatus that are particularly useful for reverse circulation of drilled cuttings out of a borehole when drilling with electrically powered tools. In such cases, the drilling fluid may be conventional mud, water, oil, an aerated system (aerated mud or foam) or pure air, with or without mist.

This wellbore-cleaning provided by the invention may be particularly suitable for drilling low pressure reservoirs, accessing unexploited fluids in reservoirs or extending the life of a depleted reservoir. Drilling these types of formations with reverse circulation and low circulating pressures can typically cause less damage to reservoir formation than drilling with direct flow circulation (drilled cuttings are in contact with the formation less, there is less susceptibility to development of washouts), and the ability of the reservoir to produce fluids is generally less compromised.

The present invention is particularly useful for drilling in overbalanced or underbalanced conditions. Underbalanced drilling is often used to avoid damaging the formation, to improve the rate of penetration and to limit problems of lost circulation.

The embodiment of the invention shown in FIG. 1 involves the deployment of a hydraulic fluid line 10 alongside an electric cable 12. The cable 12 is used to provide power and telemetry to a drilling assembly 14. In the embodiment shown in FIG. 1, the drilling assembly 14 is being used to drill a sidetrack 16 from a main borehole 18. Such operations are used to drill into bypassed reserves, or to provide extended drain holes to allow better recovery from a formation. A deflector 20 is positioned in the borehole 18 to assist the drilling assembly in initiating the sidetrack and to allow convenient re-entry if it is removed for any reason. The fluid line 10 and cable 12 are each provided with a drum 22 at the surface from which they can be fed into the borehole 18 via pressure control equipment, typically comprising annular rams and/or blind rams and including a stuffing box or grease tube 24 for the electric cable 12 and an injector and stripper 26 for the hydraulic line 10. The hydraulic line 10 can comprises one or more different hydraulic conduits. The electric cable 12 and hydraulic line 10 can be associated to form an electro-hydraulic umbilical cable as is described below.

The hydraulic line 10 may be a flexible hose compatible with the oilfield environment. The flexible hose may be constructed of:

• • Polymer liners made of extruded PTFE, PVDF, PEEK, etc.
  • Steel wire or composite re-enforced structure for pressure ratings
  • Extruded polymer cover.

The flexible hose may also be made of any such material capable of withstanding the internal and/or external pressures and the forces developed when deploying or operating the system.

The hydraulic line can also be a coiled tubing made of steel, fiberglass, composite material or any other material compatible with the oilfield environment and capable of withstanding these pressures and forces.

The electric cable 12 can be any of the standard wireline cable used in current oilfield electric line operations.

The drilling assembly 14 attached at the bottom of the circulation system described above runs on electric power supplied by the electric cable 12. These electric drilling tools provide all directional drilling means necessary to steer the well in the desired trajectory. These directional drilling means can include an orientation assembly, a drilling motor, a reverse circulating drill bit and measurement tools. The measurement tools can provide parameters including, inclination, azimuth, natural gamma ray, and formation resistivity. Such drilling tools typically communicate with surface equipment via the electric cable 12. Some data collected downhole are transmitted to surface through high-speed telemetry in the cable 12.

The drilling system can also comprise a downhole flow control valve. This prevents undesired or uncontrolled flow of fluids, particularly hydrocarbons, from downhole to surface through the hydraulic line 10. The flow control valve is capable of shutting off the flow from the wellbore 18 to the inside of the hydraulic line 10. The operation of the downhole flow control valve can be controlled mechanically (as a one-way valve, for example), or hydraulically or electrically operated.

The electric cable 12 and the hydraulic line 10 can be bundled together to form an electro-hydraulic umbilical cable as is described in more detail in relation to FIGS. 2-5 below. An electro-hydraulic umbilical cable can be used to perform some or all of the following functions:

• • Deployment of drilling or logging tools
  • Electric power transmission to downhole tools
  • 2-way high speed telemetry between downhole tools and surface equipment
  • Provide one or several flow conduits for fluid injection or hydraulic transport of cuttings

The electric cable 12 and the hydraulic line 10 can be assembled as an umbilical cable over certain length of the well or over the entire length of the well. They can also be run separately provided they are equipped with systems or means to avoid the twisting of the two cables (for example, by connecting the cable and line to each other at points along their length).

FIG. 2 shows an embodiment of the invention utilising a combined electro-hydraulic umbilical cable. In this embodiment, an umbilical cable 30 is run from the bottom hole assembly 14 up to surface. The umbilical 30 comprises an electric line and one or more flow conduits and is held on a drum 31 located at the surface of the well. The drilling medium (drilling fluid) is reverse circulated from the drill bit 32 up inside the hydraulic conduit(s) of the umbilical 30 to the surface. However, the returning drilling medium and any produced hydrocarbons cannot be circulated safely out in the drum 31 at the surface. The proximity of the electric power cable and the pressurized hydrocarbons in the drum 31 would represent a potential danger (explosion) on surface. To avoid this situation, the returning fluids are diverted from the flow conduit(s) of the umbilical cable 30 to a separate secondary hydraulic line 34 via a connection sub 36.

The secondary flow line 34 is attached directly at the connection 36 to the lower part 38 of the hydraulic line in the umbilical 30. This secondary flow line 34 may only be a few hundreds of metres long in order that it can be securely housed at the surface on a drum 40 housed in a pressure vessel 42 that can be directly connected to wellhead equipment 44. The returned fluids from downhole are diverted from the umbilical 30 into the secondary line 34 at the connection 36 and so will never flow in the drum 31 exposed on surface. Fluids returned via the secondary line 34 can be removed via a port 46 connected to a separator (not shown).

FIG. 2 shows an embodiment of the invention in which the umbilical cable 31 runs all the way from surface to the bottom of the borehole 18. In this embodiment, the electro-hydraulic umbilical 30 is made in multiple segments (see also FIG. 3), each segment being provided in one of two fixed lengths: a long one, typically a kilometre L and a short one, typically a few hundred metres I. The length I is the same length as that of the secondary hydraulic return line 34. The electric line of the umbilical can be either continuous or discontinuous at the connection points. For a continuous electric line, where there is a connection to be made, only a hydraulic connection is made alongside the continuous electric cable.

When running in hole, down to the starting depth of the first drilling run, long segments of umbilical cable 30L (and some short segments 301, if required) are joined in order to reach (or be close to the desired depth. From that depth on, the well will be drilled in runs of measured depth I.

The connection sub 36 diverts the circulating fluids from the lower hydraulic line of the umbilical cable 30 to the secondary return line 34. The connection sub 36 also maintains the electrical and mechanical links between the upper and lower parts of the umbilical cable 30. Only one such connection sub 36 is needed for the entire drilling operations. The position of the connection sub 36 is moved one segment up, to the next connection point on the umbilical 30, after each drilling run.

After running in hole down to the start depth of the run, the connection sub 36 is positioned at the last connection point to enter the wellhead and connected to the upper part of the umbilical 30 made up of short segments 30I. The secondary hydraulic line 34 is also attached to the connection sub 36. Drilling commences and the well is drilled until the next connection point is about to enter the wellhead or until the secondary hydraulic line 34 is completely un-spooled (see FIG. 4 A R1). At this point, the borehole 18 is circulated, cleaned and the position of the connection sub 36 is moved up to the top of the next segment 301:

• • The umbilical cable 30 is pulled out and the secondary line 34 is reeled back on its drum 40
  • The connection sub 36 is removed and replaced by a normal hydraulic or electro-hydraulic cable connection 38
  • The short length segment 301 is connected to the top of the umbilical
  • The umbilical cable 30 is then run in hole until the connection point at the top of the short segment 301 is at surface level
  • The connection sub 36 is then placed at that point and the secondary hydraulic return line 34 is re-connected.

The system is now ready for a new drilling run until the next connection point of the next short segment is about to enter the well at which point this process is repeated (FIG. 4 B R2).

The energy necessary for the displacement of cuttings in the secondary flow line 34 can be provided in different ways, including:

• • A downhole pump that is powerful enough to generate flow up to surface
  • A specific power fluid (water or mud), injected from surface, in one of the hydraulic conduits of the upper part of the umbilical cable 30, down to the connection sub 36 where it lifts the cuttings in the return line 34.

The secondary return line 34 can be made from various materials as described above in relation to the hydraulic line. It can be configured as:

• • A continuous length of hydraulic line
  • A hydraulic line in multiple sections
  • A hydraulic line clamped to the umbilical cable at regular intervals if there is a risk that the umbilical cable and the return line would twist together
  • Or any combination of the above options.

FIG. 5 shows another embodiment of the invention in which separate hydraulic and electric lines are connected to the top of the umbilical. In this configuration, the umbilical cable 30 is run over a certain length in the borehole 18. After the umbilical cable 30 is run in, the hydraulic and electric lines 10, 12 are separated in the rest of the well and up to surface and are operated in essentially the same manner as is described in relation to FIG. 1. The separate hydraulic line 10 can be deployed with the same configurations as the return line 34 described above:

• • Continuous hydraulic line
  • A hydraulic line in multiple sections
  • Hydraulic line housed in a pressure vessel 40 on surface
  • Hydraulic line clipped to the electric line at regular intervals
  • Or any combination of the above.

The present invention has a number of potential benefits over prior art approaches:

• • Circulation is performed using relatively small conduits (the hydraulic line(s), so requiring less power consumption to achieve the required fluid velocity to efficiently transport the cuttings and clean the hole.
  • Reverse circulation is the preferred approach which means that the drill cuttings do not remain in contact with the formation and cause less damage to the formation.
  • The drilling and circulation system could be deployed and operated in live wells conditions, avoiding the need to kill the well and potentially cause formation damage or allowing drilling while producing.
  • Because the system is relatively small by design, it is suitable for various hole sizes commonly drilled in hydrocarbon formations.
  • Only the bottom hole assembly has to be changed, and not the circulation system, when drilling different hole sizes.

The embodiments described above are only examples. The various elements of the systems and operations described can be combined and modified while still remaining within the scope of the invention.

Claims

1. Apparatus for drilling operations in underground boreholes, comprising:

a drilling assembly that can be located in a borehole and is moved along the borehole during the drilling operation;

a flexible fluid supply line connected to and in fluid communication with the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; and

an electric cable for providing electric power to the drilling assembly and extending from the drilling assembly to the surface when the drilling assembly is in the borehole; wherein

the fluid line and the electric cable are separate, the electric cable being outside the fluid line.

2. Apparatus as claimed in claim 1, wherein the fluid line and the electric cable are connected to each other in at least one location between the drilling assembly and the surface.

3. Apparatus as claimed in claim 1 or 2, further comprising at least one drum for storing and delivering the fluid line and/or cable to the well.

4. Apparatus as claimed in claim 3, wherein a separate drum is provided for the fluid line.

5. Apparatus as claimed in claim 1, wherein the fluid line and/or the electric cable is formed from segments joined end-to-end by connectors.

6. Apparatus as claimed in claim 5, further comprising a secondary fluid line connected to the fluid line in an upper region thereof.

7. Apparatus as claimed in claim 6, wherein the secondary fluid line is connected to the fluid line at the connector between the uppermost segment and the adjacent segment.

8. Apparatus as claimed in claim 4 or 7, further comprising a pressure-controlled housing, the drum of the fluid line or the secondary fluid line being located inside the housing.

9. Apparatus as claimed in claim 8, further comprising a port in the housing to allow fluid to be introduced to or withdrawn from the fluid line or secondary fluid line.

10. A method for conducting drilling operations using an apparatus as claimed in claim 1, the method comprising operating the drilling assembly and directing fluid between the surface and the drilling assembly via the flexible fluid line.

11. A method as claimed in claim 10, wherein the fluid is a drilling fluid which is introduced to the borehole at the surface and circulates from the bottom of the borehole back to the surface via the fluid line so as to carry drilled cuttings away from the drilling assembly.

12. A method as claimed in claim 10 or 11, wherein the fluid line and the electric cable are fed into or withdrawn from the borehole as the drilling assembly moves along the borehole.

13. A method as claimed in claim 10, comprising connecting the fluid line and electric cable can together in at least one point along as they are fed into the borehole.

14. A method as claimed in claim 10, wherein the fluid line and/or electric cable are formed from segments, the method comprising joining the segments with connectors as the fluid line and/or electric cable are fed into the well, or disconnecting the segments at the connectors as the fluid line and/or electric cable are withdrawn from the well.

15. A method as claimed in claim 14, further comprising connecting a secondary fluid line to the fluid line in an upper region thereof.

16. A method as claimed in claim 15, comprising connecting the secondary fluid line between the uppermost segment and the adjacent segment.

17. A method as claimed in claim 15 or 16, wherein the secondary fluid line is used to introduce or withdraw fluid from the fluid line.

18. A method as claimed in claim 15, wherein secondary fluid line is typically shorter than the fluid line, the method comprising periodically disconnecting the secondary fluid line is periodically from the fluid line and reconnecting it at another location as the fluid line is fed into or withdrawn from the borehole.

19. A method as claimed in claim 10, further comprising storing the fluid line and/or secondary fluid line can in a pressure-controlled housing.

20. A method as claimed in claim 19, wherein the housing is maintained at or near borehole pressure, the method comprising feeding the fluid line and/or secondary line between the housing and the borehole while being maintained at or near borehole pressure.