NO20141025A1 - System and method of supplementary drilling - Google Patents

Abstract

A cable or umbilical cord drilling unit (2) is described in particular for forming a second borehole (12) derived from an established first borehole (11) in a substructure (1) and for flowing an established first or second borehole (11, 12). ), the drilling unit (2) comprising a drilling section (21), a transport section (22) and at least one propulsion actuator (224, 224 ') adapted to be releasably engaged with a borehole wall (121), wherein the transport section (22) is detachable from the drill section (21) and is provided with a cuttings container (225) and is connected to a cable or umbilical (141) connected to a surface installation (13) and is adapted to transfer energy between the surface installation (13) and the transport section ( 22), and at least one of the at least one propulsion actuator (224, 224 ') and an associated hydraulic unit (221) is arranged on the transport section (22) and is arranged to be able to move the transport section (22) in the second drill. the axial direction of the e-hole (12). Methods are also described for forming a second borehole (12) derived from an established first borehole (11) in a subsurface structure (1) and for flowing an established borehole (11, 12) into a subsurface structure (1) using a cable or umbilical cord drilling unit (2).

Description

SYSTEM AND PROCEDURE FOR SUPPLEMENTARY DRILLING

The invention relates to a cable-operated drilling unit in particular for creating a second borehole derived from an established first borehole in an underground structure and for clearing an established borehole, the drilling unit comprising a drilling section, a transport section and several propulsion actuators which are arranged to be able to be in releasable engagement with a borehole wall. The invention also relates to methods for creating a second borehole derived from an established first borehole in an underground structure and for reaming an established borehole in an underground structure using a cable- or umbilical-operated drilling unit.

Drilling for oil and gas requires the use of a drilling rig with associated equipment, and the preparation, the drilling operation itself and the removal of the equipment used are expensive and time-consuming. Thus, it will often not be cost-effective to establish production wages in small reservoirs by drilling laterals from a main well, especially into small pockets that are discovered after a field has been put into production and the drilling rig has been removed and replaced by production equipment. This means that discovered hydrocarbon deposits are considered unexploitable as there are no applicable technological solutions for that type of deposits.

If formation damage occurs during production, there will similarly be a need for supplementary drilling, where it is desirable to be able to carry out this without bringing in an expensive drilling rig. It is also desirable to be able to ream parts of a borehole, i.e. expand the cross-section of the borehole without bringing in a traditional drilling rig.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

The purpose is achieved by the features indicated in the description below and in the subsequent patent claims.

A drilling unit is provided which is connected to a surface installation via an umbilical, for example a cable that the drilling unit hangs on as it is lowered into and pulled out of a borehole. Handling cable-operated equipment or autonomous equipment associated with the surface installation requires less complicated surface installations than is required for drilling operations performed with an ordinary drill string rotated by a surface-placed drilling machine.

When a side borehole is to be diverted from a lined, existing borehole, a side window is established in the existing borehole's casing in a manner known per se, for example by a drilling wedge (whipstock) which is set at a prescribed depth in the existing borehole, guides a chip-separating tool or similar in the desired direction towards the casing. The lateral borehole is formed in the underground structure of interest, for example where one expects to find hydrocarbons or at a suitable distance to a formation damage. The side borehole can be diverted in a direction away from the borehole, typically approximately horizontally and with a length usually limited to a few hundred metres. The lateral borehole is established by means of a self-propelled drilling unit driven by means of energy supply through cables from the surface installation. In a preferred embodiment, the drilling unit is electrically driven.

Correspondingly, a part of an existing borehole can be reamed, i.e. given an extended cross-section by the aforementioned self-propelled drilling unit being introduced into the part of the borehole to be processed, where the drilling unit is put into operation.

In the further description, the terms "drilling", "borehole" etc. are used without what is described being limited to the ordinary establishment of a borehole, as what is described also covers clearing operations carried out on a previously established borehole, unless otherwise stated explicitly expressed.

The drilling unit is equipped with a propulsion device that provides sufficient bit pressure against the subsoil, even when drilling horizontally. A preferred propulsion device comprises at least one first and one second propulsion actuator formed as radially expandable gaskets or gasket groups designed to be able to attach to the wall of the borehole. The propulsion actuators are characterized by the gaskets/gasket groups encircling a tubular housing on the drilling unit, where at least one of the gaskets/gasket groups is connected to a sliding sleeve that is axially displaceable on a part of the housing, as described in NO patent 328189. By the fact that the gaskets/gasket groups the packing groups alternate with lying against the borehole wall, and the axially displaceable packing or packing groups alternate between pushing the drilling unit in the axial direction by means of an associated linear actuator, for example a ring piston, while the packing/packing group is clamped in the borehole wall, and return to an initial position while the respective packing/packing group is withdrawn from engagement with the borehole wall. The gaskets/gasket groups are also designed to prevent the drilling unit from turning about its central axis as a reaction to the rotation of the drill bit when they are placed against the borehole wall. In addition to functioning as a propulsion device, the propulsion actuators will also be able to function as seals between the drilling unit and the borehole wall, and parts of the borehole can thus also be insulated. The patent publication NO 328189 is included in its entirety as a reference in this description.

The drilling unit is provided with a transport section that includes a cuttings container, as the transport section can be disconnected from a drilling section that is temporarily left in the borehole. At least one of the drilling unit's propulsion actuators is arranged on the transport section which can be moved out of the borehole for emptying the cuttings container, either by the transport section being moved by means of the propulsion actuators, pulled by the cable or moved by a combined use of these means. The cuttings are usually collected for the surface installation, but disposal in other places is not excluded, for example in the main borehole, if this is a well that has been emptied. An emptied transport section is returned to the drilling unit and connected to it so that the drilling operation can continue.

The drilling unit can be arranged to set out sand trap pipes in the finished side borehole. Sand trap pipe sections are preferably arranged to be joined in the borehole by means of the drilling unit as the borehole is established, for example by the sand trap pipe sections being brought into the borehole by means of the transport section when it returns after the cuttings container has been emptied.

The drilling unit, possibly the transport section and the drilling section separately, and any associated working and equipment sections that must be able to be connected together with the drilling unit or mounted in the side borehole, for example the sand trap pipe sections, or the main borehole, for example the drilling wedge, have a length that allows them alone or connected to another unit/section can be passed through a wellhead sluice unit. Typical maximum lock length can be up to approx. 20 meters.

The available formation fluid can be used as drilling fluid, i.e. fluid used for cooling the drilling unit and for transporting drill cuttings.

The invention is defined by the independent patent claims/the independent patent claim. The independent claims define advantageous embodiments of the invention.

In a first aspect, the invention relates more specifically to a cable- or umbilical-operated drilling unit, in particular for creating a borehole derived from an established first borehole in an underground structure and for clearing an established first or second borehole, the drilling unit comprising a drilling section, a transport section and at least one propulsion actuator which is adapted to be releasably engaged with a borehole wall, characterized in that the transport section is releasable from the drilling section and is provided with a cuttings container and is connected to a cable or umbilical which is connected to a surface installation and is adapted to be able to transfer energy between the surface installation and the transport section, and at least one of the at least one propulsion actuator and an associated hydraulic unit is arranged on the transport section and is arranged to be able to move the transport section in the axial direction of the second borehole.

The transport section can be arranged to be able to be pulled away from the drilling section by means of the cable.

The transport section can comprise at least one axially displaceable and radially expandable packing element which is designed to be placed against the borehole wall. Alternatively, the transport section may comprise at least one axially displaceable propulsion actuator which is provided with a radially expandable packing element which is designed to be placed against the borehole wall.

The transport section can form part of a transport system for drilling fluid comprising at least perforations arranged in the cuttings container and arranged to retain drilling cuttings, as well as a pump filter arranged to filter a flow of drilling fluid in the direction from the cuttings container towards a circulation pump.

At least some of the propulsion actuators may be provided on the drilling section.

At least one drilling fluid port forms a fluid flow connection from an annulus formed between the drilling assembly and a wellbore wall, and to the interior of the transport section.

At least one of the at least one radially expandable packing elements can form a flow barrier in an annulus formed between the drilling unit and the borehole wall, the packing element being arranged between a drilling fluid port that forms a fluid flow connection from the annulus formed between the drilling unit and the borehole wall, and to the interior of the transport section, and a pump filter which is arranged to filter a flow of drilling fluid in the direction from the cuttings container towards a circulation pump.

The combined length of the drilling section and the transport section, or the length of each of the drilling section and the transport section can be at most equal to the capacity of a wellhead sluice unit.

In a second aspect, the invention relates more specifically to a method for creating a second borehole derived from an established first borehole in an underground structure, characterized in that the method comprises the following steps: providing a side opening in the first borehole;

providing a cable or umbilical operated drilling unit;

sluicing the drilling unit through a wellhead sluice unit;

producing the second bore hole by rotation of a drill section drill bit arranged in a front part of the drilling unit;

filling cut cuttings into a cuttings container arranged in a transport section arranged in a rear part of the drilling unit;

to disconnect the conveying section from the drilling section;

moving the transport section out of the second borehole;

returning an empty transport section to the second borehole; and to interconnect the transport section and the drilling section.

The method may comprise the further step of:

moving the transport section out of the second borehole by pulling the transport section by means of a cable or displacing it by activating propulsion actuators arranged on the transport section.

The method may comprise the further step of:

before coupling the transport section and the drilling section to displace the transport section towards the drilling section by activating propulsion actuators arranged on the transport section.

The method may comprise the further step of:

introducing the drilling unit into the first borehole by sluicing through the sluice unit the drilling section and the transport section separated from each other, and connecting the drilling section and the transport section in the first borehole or the second borehole; respectively

separating the drilling section and the transport section in the first borehole or the second borehole, and passing the drill section and the transport section separately out of the first borehole through the sluice unit.

In a third aspect, the invention relates more specifically to a method for reaming an established borehole in an underground structure, characterized in that the method includes the following steps: providing a cable- or umbilical-operated drilling unit;

sluicing the drilling unit through a wellhead sluice unit;

reaming the borehole by expansion and rotation of a drill section drill bit arranged in a front part of the drilling unit;

filling cut cuttings into a cuttings container arranged in a transport section arranged in a rear part of the drilling unit;

to disconnect the conveying section from the drilling section;

moving the transport section out of the borehole;

returning an empty transport section to the borehole; and

to connect the transport section and the drilling section.

In what follows, an example of a preferred embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 shows a principle sketch of a borehole where a drilling unit according to the invention is in the process of forming a side borehole; and

Fig. 2 shows a side view of the drilling unit on a larger scale.

Reference is first made to Figure 1, where the reference number 1 indicates an underground structure,

where a drilling wedge 111 is arranged in an established first borehole 11 to guide an essentially cylindrical, elongated drilling unit 2 into the underground structure 1 when drilling a derived second borehole 12, also called a side borehole. The side borehole 12 is bounded against the underground structure 1 by a borehole wall 121. A surface installation 13

comprises a wellhead 131 and a sluice unit 132 for introducing equipment into the first borehole 11, in particular equipment of the type that is lowered into and pulled out of said borehole 11 by means of a cable 141 which is connected to a cable unit 14 arranged on or at the surface installation 13. Derived boreholes of this nature are typically 4-5 inches in diameter.

Alternatively, the cable 141 and the cable unit 14 can be replaced by an umbilical cord (not shown) which is not designed to be able to carry the weight of said equipment, but is suitable for the transmission of energy, control signals etc.

Reference is then made to figure 2, where the drilling unit 2 is shown in greater detail. A front drill section 21 comprises a rotatable drill bit 211 which is connected to a drive mechanism 213 comprising a motor 2131 and a first gear 2132 for adapting the rotational speed of the drill bit 211 in relation to the motor's 2131 speed. The drive 213 is also provided with a circulation pump 2133 designed for circulation of drilling fluid. The circulation pump 2133 is connected to the motor 2131 via a second gear 2134. In an embodiment not shown, the circulation pump 2133, optionally together with the motor 2131 and said gear 2134, is arranged so that it can be released from the drilling section 21 and brought up to the surface for maintenance, alone or together with the transport section 22. The drill bit 211 can be radially expandable in a manner known per se for use when reaming the existing main borehole 11 or a previously established side borehole 12.

The drilling section 21 is also provided with side control means 212 for changing the drilling direction. Finally, the drilling section 21 is provided with a unit 214 for recording relevant drilling data, typically a so-called MUB unit (measurement while drilling (MWD)). A first connecting part 215 is arranged in the rear end part of the drilling section 21 and comprises means for mechanical, lockable connection of the drilling section 21 with a transport section 22 as well as means for connecting signal lines, fluid lines etc. which extend between the drilling section 21 and the transport section 22.

Transport section 22, which in a connected position extends backwards from drilling section 21, is provided with a second coupling part 226 which is complementary to the first coupling part 215 on the drilling section. The transport section 22 is further provided with a hydraulic unit 221 provided with a control unit and is designed to at least ensure a controlled activation of several associated propulsion actuators 224 arranged on the transport section 22. In addition to being able to displace the transport section 22 in the longitudinal direction of the borehole 12, the propulsion actuators 224 could apply the necessary load to the drill bit 211 during drilling as well as prevent the drilling unit 2 from rotating as a reaction to the torque applied by the drill bit 211 during drilling.

In a preferred embodiment, the propulsion actuators 224 are of a type comprising several annular gaskets 2241 which surround a cylindrical housing, are expandable towards the nearby borehole wall 121 and are axially displaceable in the longitudinal direction of the housing by means of linear actuators (not shown). In this form, a front and a rear propulsion actuator 224, 224' alternate between being in engagement with the borehole wall 121. Reference is made to NO 328189 for a detailed description of the propulsion actuators 224 of a type where activatable gaskets are arranged externally on a cylindrical body, and the gaskets in an active state are designed to be able to seal the annular space between the body and a borehole wall, and where at least one gasket group of the activatable gaskets is connected to a sliding sleeve, so that at least one group of gaskets is displaceable relative to the cylindrical body by means of an associated linear current

dare.

The transport section 22 is further provided with a cuttings container 225 designed to collect drilling cuttings which is carried with drilling fluid from the drill bit 211 by means of the drilling section 21's circulation pump 2133 through an annulus 3 formed between the drilling unit 2 and the borehole wall 121, into through one or more drilling fluid ports 222 arranged in the transport section's 22 wall and to the cuttings container 225, where cuttings are held back while the drilling fluid flows out through perforations 2251 in the wall of the cuttings container 225 and returns to the circulation pump 2133 via a pump filter 223 and flow channels arranged thereto (not shown) in the transport section 22 and the drilling section 21. The preferred the expandable propulsion actuators 224 delimit the cuttings-containing drilling fluid flow from the cuttings-free drilling fluid flow, as the drilling fluid port(s) 224 and the pump filter 223 are arranged on each side of the propulsion actuators 224 which function as a seal between them, possibly that the sealing function is taken care of by another , no packing element shown. The preferred embodiment of the propulsion actuators 224 clearly comes into its own by its combined function of alternately expanding the expandable packing element 2241.

At its rear end, the transport section 22 is connected to the cable 14 via a cable connection 227 where the load-carrying component of the cable 141 is anchored and the other components of the cable 141 are carried on in power and signal lines (not shown) to the drive unit 213, signal lines to the MUB unit 214, etc. in suitable passages (not shown) in the transport section 22, the coupling parts 215, 226 and the drilling section 21.

Alternatively, the drilling section 21 can also be provided with several propulsion actuators (not shown) arranged for activation coordinated with or independent of the activation of the transport section 22's propulsion actuators 224.

The drilling unit 2 is advantageously powered by electric current via the motor 2131 and the hydraulic unit 221, but the invention is not limited to this, as the purpose of the invention is also achieved by the circulation of a pressurized hydraulic medium, for example hydraulic oil, from the surface installation 13 through suitable lines (not shown) associated with the cable 141 or said, not shown umbilical cord.

The total length of the drilling unit 2 is primarily within the maximum length that can be accommodated by the sluice unit 132. Alternatively, the length of each of the drilling section 21 and the transport section 22 is individually within the capacity of the sluice unit 132, and the drilling section 21 and the transport section 22 can then be sluiced in or out separately, as the connection is made in the first borehole 11 or in the second borehole

easy 12.

When a second borehole 12 is to be provided as a branch from an existing first borehole 11 in the underground structure 1, for example to extract hydrocarbons from an assumed small pocket or to inject water into the structure, a drill wedge 111 is first driven down into the first borehole 11 and anchored in a desired position. A side opening 113 is then established in the casing 112 of the first drill hole 11 with a suitable tool (not shown). The drilling unit 2 according to the invention is then sluiced into the first borehole 11 as a unit, optionally separated as drilling section 21 and transport section 22 which are connected together in the first borehole 11. The drilling unit 2 is then put into operation and drills out the second borehole 12, as the drill bit 211 is rotated and the direction is controlled, and the drilled cuttings are collected in the cuttings container 225.

When the cuttings container 225 is full, the drilling is stopped, the transport section 22 is disconnected from the drill section 21, and the transport section 22 is pulled out of the second drill hole 12 by means of the cable unit 14 and the cable 141, possibly out of the first drill hole 11, and emptied of drill cuttings. The transport section 22 is then introduced into the second borehole 12 again and connected to the borehole section 21. When the second borehole 12 eventually deviates a lot from the direction of the first borehole 11 and has gained such a small rise that the transport section 22 does not slide out of the second borehole under its own weight borehole 12, the transport section 22's propulsion actuators 224 can be activated for assisted propulsion of the transport section 22 in that the transport section 22 has energy supply through the cable 141 to the integrated hydraulic unit 221.

When the transport section 22 is connected to the drilling section 21, the energy supply and signal connection between the drilling section 21 and the surface installation 13 is restored, and the drilling operation can continue.

In an embodiment not shown, the cuttings container 225 is arranged to be able to dump its content of cuttings into the first drill hole 11, typically in a situation where the first drill hole 11 is no longer producing. This can be achieved, for example, by arranging the cuttings container 225 closest to the drilling section 21, and by the drilling wedge 111 being provided with passages for the cuttings that are dumped.

In a further embodiment (not shown), the transport unit 22 is designed to be able to bring with it and place well components (not shown) in the second borehole 12, for example sand traps.

When a part of an established borehole, for example said lead borehole 11 or said second borehole 12, is to be reamed, i.e. the cross-section is to be widened, the drilling unit 2 according to the invention is sluiced into the first borehole 11 as described above and led to the part which must be processed. The drilling unit 2 is then put into operation and expands the borehole 11, respectively 12, as the drill bit 211 is expanded and rotated, and the drilled cuttings are collected in the cuttings container 225.

Claims (14)

1. Cable- or umbilical-operated drilling unit (2) in particular for creating a second borehole (12) derived from an established first borehole (11) in an underground structure (1) and for clearing an established first or second borehole (11, 12) , the drilling unit (2) comprising a drilling section (21), a transport section (22) and at least one propulsion actuator (224, 224') which is arranged to be in releasable engagement with a borehole wall (121), characterized in that the transport section (22) is detachable from the drilling section (21) and is provided with a cuttings container (225) and is connected to a cable or umbilical cord (141) which is connected to a surface installation (13) and is arranged to be able to transfer energy between the surface installation (13) and the transport section ( 22), and at least one of the at least one propulsion actuator (224, 224') and an associated hydraulic unit (221) is arranged on the transport section (22) and is arranged to be able to move the transport section (22) in the second borehole (12) axial direction. 2. Drilling unit (2) according to claim 1, where the transport section (22) is arranged to be able to be pulled away from the drilling section (21) by means of the cable (141). 3. Drilling unit (2) according to claim 1, where the transport section (22) comprises at least one axially displaceable and radially expandable packing element (2241) which is designed to be placed against the borehole wall (121). 4. Drilling unit (2) according to claim 1, where the transport section (22) comprises at least one axially displaceable propulsion actuator (224, 224') which is provided with a radially expandable packing element (2241) which is arranged to be placed against the borehole wall ( 121). 5. Drilling unit (2) according to claim 1, where the transport section (22) forms part of a transport system for drilling fluid comprising at least perforations (2251) which are arranged in the cuttings container (225) and arranged to retain drilling cuttings, and a pump filter (223) arranged to filter a flow of drilling fluid in the direction from the cuttings container (225) towards a circulation pump (2133). 6. Drilling unit (2) according to claim 1, where at least some of the propulsion actuators (224) are arranged on the drilling section (21). 7. Drilling unit (2) according to claim 1, wherein at least one drilling fluid port (222) forms a fluid flow connection from an annulus (3) formed between the drilling unit (2) and the borehole wall (121) and to the interior of the transport section (22) ). 8. Drilling unit (2) according to claim 3 or 4, where at least one of the at least one radially expandable packing element (2241) forms a flow barrier in an annular space (3) that is formed between the drilling unit (2) and the borehole wall (121 ), the packing element (2241) being arranged between a drilling fluid port (222) which forms a fluid flow connection from the annulus (3) which is formed between the drilling unit (2) and the borehole wall (121), and to the interior of the transport section (22), and a pump filter (223) which is designed to filter a flow of drilling fluid in the direction from the cuttings container (225) towards a circulation pump (2133). 9. Drilling unit (2) according to claim 1, where the total length of the drilling section (21) and the transport section (22), or the length of each of the drilling section (21) and the transport section (22) is at most equal to the capacity of a wellhead (131) sluice unit (132). 10. Method of drilling for creating a second borehole (12) derived from an established first borehole (11) in an underground structure (1), characterized in that the method comprises the following steps: providing a side opening (113) in the first borehole (11) ); providing a cable or umbilical operated drilling unit (2); sluicing the drilling unit (2) through a wellhead (131) sluice unit (132); producing the second borehole (12) by rotation of a drill bit (211) of a drilling section (21) arranged in a front part of the drilling unit (2); filling cut cuttings into a cuttings container (225) arranged in a transport section (22) connected to a rear part of the drilling unit (2); disconnecting the conveying section (22) from the drilling section (21); moving the transport section (22) out of the second borehole (12); returning an empty transport section (22) to the second wellbore (12); and connecting the conveying section (22) and the drilling section (21). 11. Method according to claim 10, wherein the method comprises the further step of: moving the transport section (22) out of the second borehole (12) by pulling the transport section (22) by means of a cable (22) or displacing it by to activate propulsion actuators (224) provided on the transport section (22). 12. Method according to claim 10, wherein the method comprises the further step: before connecting the transport section (22) and the drilling section (21) to displace the transport section (22) towards the drilling section (21) by activating propulsion actuators (224) arranged on the transport section ( 22). 13. Method according to claim 10, wherein the method comprises the further step: introducing the drilling unit (2) into the first borehole (11) by sluicing through the sluice unit (132) the drilling section (21) and the transport section (22) separately from each other , and connecting the drilling section (21) and the transport section (22) in the first borehole (11) or the second borehole (12); respectively to separate the drilling section (21) and the transport section (22) in the first borehole (11) or the second borehole (12), and to lead the drilling section (21) and the transport section (22) separately out of the first borehole (11) through the sluice unit (132). 14. Procedure for drilling for clearing an established borehole (11, 12) in an underground structure (1), characterized in that the procedure comprises the following steps: providing a cable or umbilical operated drilling unit (2); sluicing the drilling unit (2) through a wellhead (131) sluice unit (132); reaming the drill hole (11, 12) by expansion and rotation of a drilling section (21) drill bit (211) arranged in a front part of the drilling unit (2); filling cut cuttings into a cuttings container (225) arranged in a transport section (22) connected to a rear part of the drilling unit (2); disconnecting the conveying section (22) from the drilling section (21); moving the transport section (22) out of the borehole (11, 12); returning an empty transport section (22) to the borehole (11, 12); and connecting the conveying section (22) and the drilling section (21).