FIELD OF INVENTION

This invention relates to a method and apparatus for extracting fluid from coal-seams. More particularly, this invention relates to a method and apparatus for extracting fluid from coal-seams involving an improved communication to, from and/or between underground gas or liquid sources. Most particularly, this invention relates to a method and apparatus for extracting fluid from coal-seams involving improved fluid communication to, from and/or between underground fluid reservoirs and coal-seams without fracture stimulation of the strata.

BACKGROUND ART

The following references to and descriptions of prior proposals or products are not intended to be, and are not to be construed as, statements or admissions of common general knowledge in the art. In particular, the following prior art discussion should not be assumed to relate to what is commonly or well known by the person skilled in the art, but to assist in the inventive process undertaken by the inventor(s) and in the understanding of the invention.

Methods have been described involving drilling a bore into a coal seam to extract coalbed methane (CBM). A problem with this approach is that the coal seam may be soft and there is a risk of it collapsing on itself. This can make the material difficult to bore. Problems are often encountered in attempting to drill significant distances because of the tendency for the material to collapse.

Therefore, there is a need for an alternative method for recovering gas and/or liquids, such as CBM and other hydrocarbons, from gas and/or liquid reservoirs, especially soft geological materials such as coal, shale or sand.

Prior art attempts may involve environmentally unpalatable fracking. There is consumer, governmental and industry motivation and pressure to promote sustainable coal-seam gas extraction.

An object of the present invention is to ameliorate one or more of the aforementioned disadvantages of the prior art or to at least provide a useful alternative thereto.

STATEMENT OF INVENTION

The invention according to one or more aspects may be as defined in the independent claims. Some optional and/or preferred features of the invention are defined in the dependent claims.

Accordingly, in one aspect of the invention there is provided:

An apparatus, optionally including a combination of operational equipment, for effecting liquid or gas communication to, from or between strata comprising at least one gas and/or liquid containing source, the at least one source having an upper boundary through which an access well and/or boreholes are drilled whereby to extend the access well downwardly to a location within, above and/or below the at least one source, and to drill the access well laterally within, above and/or below the at least one source, the apparatus including a jetting device that is adapted to be inserted into the access well and characterised in that: the jetting device is adapted to form multiple boreholes extending from a lateral portion of the access well which are in multiple substantially radial orientations about the lateral portion without fracture stimulation of the strata.

In another aspect of the invention, there is provided:

A drilling method for extracting coalbed methane (CBM) including deploying an apparatus, optionally including a combination comprising two or more components of operational equipment, to effect fluid communication to, from or between strata comprising at least one gas and/or liquid containing source having a boundary, wherein the method steps include drilling an access well whereby to extend it to a location within or above the at least one source, characterised in that the method further includes: drilling laterally within the at least one source to form a lateral portion of the access well; and using a jetting device that is adapted to be inserted into the access well to form at least one channel extending outwardly from the lateral portion without fracture stimulation of the strata.

The method may include the step of using a horizontal well for jetting purposes.

The method may include the step of using a lateral well drilled above the coal seam.

The method may include the step of using a lateral well drilled through the coal seam.

The method may include the step of using a lateral well drilled between multiple coal seams.

The method may include the step of using a lateral well drilled through multiple coal seams.

The method may include the step of using a lateral well below the coal seam.

The method may include the step of using a lateral well drilled “within” a shale reservoir.

Boundary

The upper boundary may be a transition in phase or composition of solids, liquids or gases underground such as a transition between clay and shale. The at least one reservoir may include a lower boundary located underneath or deeper underground than the upper boundary. In this specification, the terms “upper boundary” and “lower boundary” will be referred to as “boundaries”.

The boundaries may be consolidated boundaries having clear outer margins. The boundary may be a definite or clear boundary.

The boundaries may include a transition between geological substrates such as clay, shale, rock, loam, sand, sandstone and/or other naturally occurring underground solids, liquids or gasses. The boundaries may include a transition between rock, sandstone or clay and a methane reservoir.

Gas and/or liquid containing source

The at least one gas and/or liquid containing source may include at least one reservoir. The at least one gas and/or liquid containing source may include multiple small pockets of liquid or gas. The at least one gas and/or liquid containing source may include liquid or gas permeated through a geological solid. The at least one gas or liquid containing source may include multiple small pockets of liquid and/or gas spread throughout a geological substrate in a swiss cheese or sponge pattern. The at least one gas or liquid containing source may include methane in shale or a coal seam. The liquid and/or gas of the liquid and/or gas containing source may include crude oil or methane.

Access well

The access well may be drilled using a bore drill with a head adapted to physically crush, cut and/or remove material from the access well. The bore drill may include a water jet to crush, cut and/or remove material from the access well. The access well may be between 10m and 1000m deep. The access well may be up to 15km long in the lateral direction. The access well may be up to 10km long in the lateral direction. In this specification, a “lateral direction” or a “lateral portion” refers to a direction or a portion having a vector component that is parallel to a ground surface, or transverse or perpendicular to the direction of the force of earth’s gravity.

The access well may be adapted to drill laterally through the liquid and/or gas containing source. The access well may be adapted to drill laterally through multiple liquid and/or gas containing sources. The access well may be adapted to drill laterally above the liquid and/or gas source. The access well may be adapted to drill laterally below the liquid and/or gas source.

Jetting device

The jetting device may include a coil, tube or pipe adapted to extend from the ground surface to a nozzle head of the jetting device. The coil may be adapted to supply liquid or gas to the nozzle head of the jetting device. The coil may be adapted to provide tension between the nozzle head and other components about the ground surface.

The nozzle head may be adapted to jet liquid or gas at multiple angles from the nozzle head. The nozzle head may be adapted to jet liquid or gas both in forward and reverse directions along the access well. The nozzle head may be adapted to propel the nozzle head and jetting device forward and/or backwards along the access well. The nozzle head may include nozzles adapted to erode channels at an angle between 1° and 90° from a longitudinal axis of the access well. The nozzle head may include nozzles adapted to erode channels at the angle, wherein the angle is between 30° and 60° from the longitudinal axis of the access well. Preferably, the nozzle head includes nozzles adapted to erode channels at the angle, wherein the angle is between 40° and 50° from the longitudinal axis of the access well.

Preferably, the nozzle head is adapted to jet water from the nozzle head. Preferably, the nozzle head is adapted to jet water out of the nozzles. Most preferably, the nozzles are adapted and orientated to both jet water to erode channels and propel the nozzle head along the access well.

The jetting device may be adapted to jet bore holes downwardly and/or upwardly relative to a nominally horizontal longitudinal axis of the nozzle). The jetting device may be adapted to jet bore holes at an angle having a range of 360° rotationally around or radially outwardly into and through the access well wall.

The jetting device may be adapted to jet bore holes up to 100m (metres) from the access well. Preferably, the jetting device is adapted to jet boreholes up to 50m from the access well.

The jetting device may be adapted to jet bore holes at intervals along the access well. The jetting device may be adapted to jet boreholes at regular intervals along the access well.

The jetting device is preferably adapted to create the multiple radial boreholes without fracture stimulation of the strata. The jetting device is preferably adapted to create the multiple substantially radial boreholes without fracking damage to the strata containing the at least one source or reservoir.

Preferably, the apparatus further includes a diverter or deflector that is adapted to redirect, divert or deflect fluid jetted from the nozzle head at the angle. The diverter may comprise one or more deflectors to redirect jetted fluid in the desired direction to achieve erosion of earth material and each one of the boreholes.

The diverter may include an in-built rotation system. The diverter may form part of a diverter system including a remote control facility. The diverter system may be adapted to allow for control at ground level or otherwise for remote control.

The diverter system may include sensors. The sensors may facilitate responsively controlled jetting of the nozzle head.

The diverter system may include a diverting device. The diverting device may be adapted to change the angle of a jetting tubing exit. The angle may be between 0 - 90, more preferably 30 - 60, still more preferably 40 - 50, and ideally 45 degrees.

The jetting device may include jetting tubing to effect the jet stream. The jetting tubing may be in the form of capillaries. The jetting device may include capillary tubing. Preferably, the jetting tubing includes stainless steel capillary tubing.

The tubing may be directed into the strata formation through the diverting device. This may be for a distance of the order of 10m - 200m, and preferably a distance of 20 to 100 metres. The substantially radially extending boreholes may be formed at intervals in a 360 degree orientation from the horizontal wellbore. The jetting device operates at selected intervals along part of or an entire length of the horizontal wellbore. In considering the term “substantially radially” extending boreholes, the term is considered to include within its scope a borehole with a vector component having a radial direction relative to the lateral portion, so that the borehole may extend at an angle to a radial direction extending perpendicular from the lateral portion.

It will be appreciated that any of the features described herein can be used in any combination, and that the invention as described in respect of the second aspect may have the specific features referred to above in respect of the invention as described in respect of the first aspect.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may be better understood from the following non-limiting description of preferred embodiments, in which:

Figure 1 is a cross sectional view of a nozzle head of a jetting device of an apparatus or combination of operational equipment jetting water in an access well.

Figure 2 is a cross-sectional view of the access well underground going through a liquid and/or gas reservoir.

Figure 3 is a cross-sectional view of the access well underground going through multiple liquid and/or gas reservoirs.

Figure 4 is a perspective view of a lateral portion of the access well with multiple boreholes shown in dotted lines.

Figure 5a is a front cross sectional view of a bore drill.

Figure 5b is a right side view of the bore drill.

DETAILED DESCRIPTION OF THE DRAWINGS

Preferred features of the present invention will now be described with particular reference to the accompanying drawings. However, it is to be understood that the features illustrated in and described with reference to the drawings are not to be construed as limiting on the scope of the invention. In describing the various embodiments of the invention, like features will be referred to using like references, with references for features of each embodiment generally preceded by 1, 2, 3, or followed by a Roman numeric sequence, such as i, ii, iii, etc. or an alphabetical sequence such as a, b, c, relative to the corresponding feature of the first embodiment. For example, a feature 10 of the first embodiment may represented as 110, 210, 310, (or nlO), or 10a, 10b, 10c, (or lOx) or lOi, lOii, lOiii, (or lOr) etc. in second, third and fourth embodiments, respectively.

An apparatus or combination of operational equipment 1 for effecting liquid or gas communication to, from or between at least one gas and/or liquid containing source 3a,b forming part of a strata. The at least one source 3a,b having an upper boundary 5 through which an access well 20 is drilled. The access well 20 extending downwardly to a location within the reservoir 3a, b. The access well 20 also drilled laterally within the at least one source 3a, b. The upper boundary 5 being a transition 5 in phase or composition of solids, liquids or gases underground such as a transition between clay 7 and shale 9. The apparatus or combination of operational equipment 1 including a jetting device 10 for insertion into the access well 20. The jetting device 10 adapted to jet multiple boreholes 22 from a lateral portion 2 la of the access well at multiple radial orientations 23 around the lateral portion 21a relative to a vertical. The jetting device 10 is adapted to avoid fracking or fracture stimulation of the strata.

The apparatus or combination of operational equipment 1 includes a bore drill. A method of using the apparatus or combination of operational equipment 1 to extract methane from natural underground methane sources 3a,b such as in shale includes the following. The apparatus or combination of operational equipment 1 drilling the access well 20 vertically downwards underground into or at the depth of the methane source 3a, b. The access well may also be drilled in a direction with horizontal vectors but preferably vertically to ensure the path of the access well to the underground methane sources 3a, b. In Figs. 5a-b, a nozzle 11 for a bore drill 30 that is suitable for use according to the invention is shown. In Fig. 1, a nominally horizontal longitudinal axis A of the nozzle 11 is shown.

The bore drill 30 is adapted to rotate at least one jet 37 to change or maintaining the direction that the bore drill 30 is moving in as it is drilling the access well.

The bore drill 30 is adapted to be remotely controlled via the surface or above ground. The bore drill includes batteries 32 to power the componentry, the rotation and general operation of the bore drill 30. The bore drill 30 may include sensors 35 such as accelerometers, elevation sensors (adapted to measure depth) and electronic gyroscopes. The bore drill 30 further includes a drilling jet 34 adapted to drill the access well 20.

After drilling vertically downwards with the bore drill 30, the bore drill then drills laterally through the underground methane source 3a (as shown in Fig. 2) or through a region containing multiple underground methane sources 3b (as shown in Fig. 3). After the access well 20 is drilled, the jetting device 10 is inserted into the access well 20. The jetting device 10 includes a nozzle head 11 attached to a tube 12. The jetting device 10 further includes a coil 13 which runs between above ground and the nozzle head 11. The coil 13 runs through the tube 12. The coil 13 acts as a spring and applies a forces in the backwards direction along the access well 3 towards the ground surface 7 or open end of the access well 3.

The tube 12 supplies water to the nozzle head 11 through a pump system including a pump above or near the ground surface 7. The nozzle head 11 includes nozzles l la-d. The nozzle head 11 includes at least 2 nozzles, preferably at least 4 nozzles 1 la-d.

The nozzles l la-d include borehole nozzles l la-d. The borehole nozzles l la-d face laterally from a longitudinal line 23 along the access well 3. The boreholes l la-d are orientated so that jets out of the boreholes nozzles 1 la-d are angled at between 40°-50° from the longitudinal line 23 along the access well 3. The jets are jets of water in the shape of a single stream or a narrow cone. The boreholes 4 created by the borehole nozzles l la-d branch off from the access well 3 at, at least 2, preferably 4, radial locations around the access well 3.

The boreholes 4 branch off from the access well 3 to access more of the underground methane source 3a or other proximal underground methane sources 3b. Therefore, advantageously, the boreholes 4 enable extraction of more methane from the methane source 3a or more methane from other proximal methane sources 3b without needing to drill multiple access wells 3.

Therefore, the apparatus or combination of operational equipment 1 is adapted to access a gas or liquid source from a large 3 -dimensional volume underground without the use of multiple access wells or only with a single access port from the ground surface.

The apparatus further includes a diverter or deflector that is adapted to redirect, divert or deflect fluid jetted from the nozzle head at the angle.

The diverter includes an in-built rotation system.

The diverter forms part of a diverter system including a remote control facility. The diverter system may be adapted to allow for control at ground level or otherwise for remote control.

The diverter system includes sensors. The sensors facilitate responsively controlled jetting of the nozzle head.

The diverter system is adapted to change the angle of a jetting tubing exit. The angle may be between 0 - 90, more preferably 30 - 60, still more preferably 40 - 50, and ideally 45 degrees.

The jetting device include jetting tubing to effect the jet stream. The jetting tubing is in the form of capillaries. The jetting tubing includes stainless steel capillary tubing. The jetting device includes capillary tubing which is directed into the formation through the diverting device for a distance of 20 to 100 metres in segmented intervals in a 360 degree orientation from the horizontal wellbore. The jetting device operates at selected intervals along part of or an entire length of the horizontal wellbore.

Throughout the specification and claims the word “comprise” and its derivatives are intended to have an inclusive rather than exclusive meaning unless the contrary is expressly stated or the context requires otherwise. That is, the word “comprise” and its derivatives will be taken to indicate the inclusion of not only the listed components, steps or features that it directly references, but also other components, steps or features not specifically listed, unless the contrary is expressly stated or the context requires otherwise.

In the present specification, terms such as “apparatus”, “means”, “device” and “member” may refer to singular or plural items and are terms intended to refer to a set of properties, functions or characteristics performed by one or more items or components having one or more parts. It is envisaged that where an “apparatus”, “means”, “device” or “member” or similar term is described as being a unitary object, then a functionally equivalent object having multiple components is considered to fall within the scope of the term, and similarly, where an “apparatus”, “assembly”, “means”, “device” or “member” is described as having multiple components, a functionally equivalent but unitary object is also considered to fall within the scope of the term, unless the contrary is expressly stated or the context requires otherwise. In the present specification, the phrase “and/or” refers to severally or any combination of the features. For example, the phrase “feature 1, feature 2 and/or feature 3” includes within its scope any one of the following combinations: Feature 1 or feature 2 or feature 3; feature 1 and feature 2 or feature 3; feature 1 or feature 2 and feature 3; feature 1 and feature 3 or feature 2; feature 1 and feature 2 and feature 3.

The meaning of descriptive, precise or absolute terms such as “flexed”, “normal”, “parallel”, “horizontal”, “vertical” or “fully” includes the preceding qualifier “substantially or almost”, unless the context or contrary is expressly indicated.

Qualifying relative terms, such as “relatively”, “sufficiently”, “near”, “almost” or “substantially”, may be taken to indicate a variation in an absolute value of between 0° and 10° or between 0% and 10%, relative to the absolute value. For example, “near horizontal” may be taken to mean any orientation between 0° and 10° relative to the horizontal.

Where the word “for” is used to qualify a use or application of an object term, the word “for” is only limiting in the sense that the device or component should be “suitable for” that use or application.

In the present specification, the term “integral” means formed of one body in a single process. In particular, the term “integrally formed” means formed of the one body without post-forming attachment of separately formed component parts. That is, “integrally formed” and the similar term “unitarily formed” mean formed in a single forming process and do not include post-forming attachment of component parts by means of fastener or other component fixing substances or methods.

Orientational terms used in the specification and claims such as vertical, horizontal, top, bottom, upper and lower are to be interpreted as relational and are based on the premise that the component, item, article, apparatus, device or instrument will usually be considered in a particular orientation, which will usually be apparent from the context.

In the present specification, the term “integral” means formed of one body in a single process. In particular, the term “integrally formed” means formed of the one body without post-forming attachment of separately formed component parts. That is, “integrally formed” and the similar term “unitarily formed” mean formed in a single forming process and do not include post-forming attachment of component parts by means of fastener or other component fixing substances or methods.

The articles "a" and "an" are used herein to refer to one or to more than one (i.e. to at least one) of the grammatical object of the article. By way of example, “an element” means one element or more than one element. It will be appreciated by those skilled in the art that many modifications and variations may be made to the methods of the invention described herein without departing from the spirit and scope of the invention. The features and components of each of the embodiments of the invention described in the detailed description and/or depicted in the accompanying drawings may be interchangeable as required, with regard to functional equivalency and compatibility. A feature or component described with reference to one but not all embodiments, if functionally and dimensionally compatible as an addition with another embodiment herein described, or substitutable with a corresponding feature or component of that other embodiment in relation to which it has not been expressly described, should be read as a potential addition or substitution to that other embodiment and as being within the scope of the invention. Furthermore, in considering a feature or component that is described in relation a particular embodiment but may be omitted from the embodiment without losing the functionality characterising the invention and without departing from the scope of the invention, unless the context and expressions used in describing the embodiment imputes that the feature or component is essential to the invention as broadly described, the omittable feature or component may be read as not being included in the embodiment.