US20260092505A1
SYSTEM AND METHOD FOR GEOTHERMAL WELL INSTALLATION
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
Schlumberger Technology Corporation
Inventors
Sylvain Thierry
Abstract
A system and method are provided for installing a well for a borehole heat exchanger. The method includes drilling a hole formation to a predetermined depth relative to a ground surface, including operating a bottomhole assembly (BHA) including a drill bit supported at a bottom end of a cable positioned within a flexible tube. After drilling the hole formation to a predetermined depth, the BHA is retracted through the flexible tube to remove the BHA from the hole formation while the flexible tube remains in the hole formation.
Figures
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001]This application claims priority to and the benefit of European Patent Application No. EP24306614.9, filed Oct. 1, 2024, which is incorporated herein by reference in its entirety.
BACKGROUND
[0002]Geothermal energy systems utilize the relatively stable temperature of the earth to provide heating and cooling for buildings through ground source heat pumps and borehole heat exchangers. These systems typically involve drilling wells to predetermined depths and installing closed loop circuits that circulate fluid to transfer heat between the building and the ground. Conventional drilling methods for geothermal installations often involve dual string configurations with multiple drilling rods and casings, which can be time-consuming and labor-intensive operations requiring multiple operators and frequent pipe connections. The drilling process typically involves larger diameter holes to accommodate the drilling equipment and completion hardware, resulting in increased excavation volumes, higher cement requirements, and greater overall installation costs. Additionally, traditional installation methods may involve separate phases for drilling, probe installation, and cementing operations, each contributing to the total time and expense of geothermal well construction.
SUMMARY
[0003]In one independent aspect, a method is provided for installing a well for a borehole heat exchanger, the method including: drilling a hole formation to a predetermined depth relative to a ground surface, drilling the hole formation including operating a bottom hole assembly (BHA) including a drill bit supported at a bottom end of a cable, the cable positioned within a flexible tube; and after drilling the hole formation to a predetermined depth, retracting the BHA through the flexible tube to remove the bottom hole assembly from the hole formation while the flexible tube remains in the hole formation.
[0004]In some aspects, the method further includes, after drilling the hole formation to a predetermined depth and prior to retracting the BHA, operating a latch to uncouple the BHA from a lower end of the flexible tube.
[0005]In some aspects, the method further includes, after retracting the BHA, securing the flexible tube within the hole formation by inserting cement between an outer surface of the flexible tube and an inner surface of the hole formation.
[0006]In some aspects, the method further includes securing the flexible tube within the hole formation by heating the flexible tube and moving a mechanical conforming device through the flexible tube to deform the tube radially outward against a surface of the hole formation, wherein the mechanical conforming device is optionally part of the BHA.
[0007]In some aspects, the method further includes, after retracting the BHA, inserting at least one inner tube through the flexible tube to form the borehole heat exchanger.
[0008]In some aspects, inserting an inner tube through the flexible tube includes inserting a bottom tube sealing assembly to facilitate fluid circulation between the flexible tube and the inner tube in a closed loop manner.
[0009]In some aspects, drilling the hole formation includes drilling the hole with a reamer in an extended state in which an outer diameter of the reamer is larger than a diameter of the flexible tube, and the method further includes, after drilling the hole formation to a predetermined depth and prior to retracting the BHA, moving the reamer to a collapsed state in which the outer diameter of the reamer is smaller than the diameter of the flexible tube. The reamer is optionally part of the BHA.
[0010]In another independent aspect, a system is provided for installing a well for a ground source heat pump application, the system including: a cable, such as a wireline, having a lower end; a bottom hole assembly (BHA) supported adjacent the lower end of the cable, the BHA including a drill bit operable to excavate a hole; and a flexible tube extending around the cable, a lower end of the flexible tube being removably coupled to the BHA, wherein, while the flexible tube is coupled to the BHA, the flexible tube is movable with the BHA as the drill bit excavates the hole, and, while the flexible tube is uncoupled from the BHA, the flexible tube remains within the hole as the drill bit is removed from the hole.
[0011]In some aspects, the flexible tube is made from polyethylene.
[0012]In some aspects, the BHA is removably coupled to the flexible tube by a latch.
[0013]In some aspects, the BHA further includes a reamer, the reamer being removably coupled to the flexible tube, the reamer being movable between an extended state and a collapsed state, an outer diameter of the reamer being larger than a diameter of the flexible tube in the extended state, the outer diameter of the reamer being smaller than the diameter of the flexible tube in the collapsed state.
[0014]In some aspects, while the flexible tube is uncoupled from the BHA, the cable and the BHA are retractable through the flexible tube to leave the flexible tube within the hole.
[0015]In some aspects, the system further includes an inner tube insertable into the flexible tube while the drill bit is removed from the hole.
[0016]In some aspects, the system further includes a bottom tube sealing assembly to facilitate fluid circulation between the inner tube and a space positioned between the flexible tube and an outer surface of the inner tube in a closed loop manner.
[0017]In some aspects, the system further includes a heating element for heating the flexible tube; and a mechanical conforming device, the mechanical conforming device movable through the flexible tube to deform the tube radially outward against a surface of the hole.
[0018]In some aspects, the heating element and the mechanical conforming device are arranged on the BHA.
[0019]In another independent aspect, a system is provided for heat exchange in a borehole, the system including an outer tube positioned within a drilled hole formation, the outer tube including a flexible thermoplastic material; an inner tube positioned within the outer tube to form a coaxial configuration; and a closed loop circuit formed between the outer tube and the inner tube configured to circulate heat transfer fluid between a ground source heat pump and the drilled hole formation.
[0020]In some aspects, the outer tube is secured within the drilled hole formation by cement positioned between an outer surface of the outer tube and an inner surface of the drilled hole formation.
[0021]In some aspects, the outer tube is deformed radially outward against a surface of the drilled hole formation to secure the outer tube within the drilled hole formation.
[0022]In some aspects, the system further includes a bottom sealing assembly positioned at a lower end of the inner tube and configured to direct fluid circulation between the inner tube and an annular space between the outer tube and the inner tube.
BRIEF DESCRIPTION OF THE DRAWINGS
[0023]In order to describe the manner in which the above-recited and other features of the disclosure can be obtained, a more particular description will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. For better understanding, the like elements have been designated by like reference numbers throughout the various accompanying figures. While some of the drawings may be schematic or exaggerated representations of concepts, at least some of the drawings may be drawn to scale. Understanding that the drawings depict some example embodiments, the embodiments will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
[0024]
[0025]
[0026]
[0027]
[0028]
[0029]
DETAILED DESCRIPTION
[0030]Before any embodiments are explained in detail, it is to be understood that the embodiments are not limited in its application to the details of the configuration and arrangement of components set forth in the following description or illustrated in the accompanying drawings. The embodiments are capable of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof are meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings.
[0031]Relative terminology, such as, for example, “about,” “approximately,” “substantially,” and the like, used in connection with a quantity or condition would be understood by those of ordinary skill to be inclusive of the stated value and has the meaning dictated by the context (for example, the term includes at least the degree of error associated with the measurement accuracy, tolerances (for example, manufacturing, assembly, use, and the like) associated with the particular value, and the like). Such terminology should also be considered as disclosing the range defined by the absolute values of the two endpoints. For example, the expression “from about 2 to about 4” also discloses the range “from 2 to 4.” The relative terminology may refer to plus or minus a percentage (for example, 1%, 5%, 10%, or more) of an indicated value.
[0032]Functionality described herein as being performed by one component may be performed by multiple components in a distributed manner. Likewise, functionality performed by multiple components may be consolidated and performed by a single component. Similarly, a component described as performing particular functionality may also perform additional functionality not described herein. For example, a device or structure that is “configured” in a certain way is configured in at least that way but may also be configured in ways that are not explicitly listed.
[0033]The present disclosure relates to using a flexible tube (e.g., coil tubing) that both provides an outer tube during drilling and is left in place to serve as an outside tube for a completion of a co-axial geothermal well.
[0034]The present disclosure relates to systems and methods for installing wells for borehole heat exchangers that may be used in conjunction with ground source heat pump applications. The disclosed approach provides a streamlined drilling and installation process that addresses various challenges associated with conventional geothermal well construction techniques. In some cases, the system utilizes a flexible tube that serves dual functions throughout the installation process, thereby reducing operational complexity and associated costs.
[0035]The flexible tube functions as both a drilling component and a permanent element of the completed borehole heat exchanger system. During the drilling phase, the flexible tube may be positioned around a cable that supports a bottom hole assembly containing drilling equipment. The flexible tube advances with the drilling assembly as the hole formation progresses to a predetermined depth. In some cases, the flexible tube may be constructed from materials suitable for both drilling operations and long-term geothermal applications, such as polyethylene or other thermoplastic materials that provide adequate strength and thermal properties.
[0036]After drilling operations reach the target depth, the bottom hole assembly may be decoupled from the flexible tube and retracted through the interior of the flexible tube. The flexible tube remains in position within the drilled hole formation, where the flexible tube becomes the outer component of a coaxial heat exchanger configuration. In some cases, an inner tube may subsequently be inserted through the flexible tube to complete the closed-loop circulation system. This approach eliminates the need for separate drilling casing removal operations that are typically associated with conventional geothermal well installation methods.
[0037]The system may provide various operational advantages compared to traditional dual-string drilling configurations. In some cases, the continuous nature of the flexible tube eliminates the need for frequent pipe connections during drilling operations, which may reduce drilling time and personnel requirements. The flexible tube configuration may also allow for reduced drilling diameters compared to conventional approaches, which may decrease the volume of excavated material and reduce cement requirements for well completion. In some cases, the system may accommodate various drilling trajectories, including vertical, slanted, or deviated well paths, depending on site-specific requirements and geological conditions.
[0038]
[0039]The BHA 106 may also include one or more steering components 114 to facilitate a steering capability (e.g., rotary steerable, bent motor), as well as Logging While drilling (LWD) and/or Measurement While Drilling (MWD) telemetry, and a latch system 116 that removably couples the BHA 106 to the lower end of the flexible tube 104 such that the latch system 116 may uncouple the BHA 106 from the lower end of the flexible tube 104. Connected to the BHA 106 and located inside the plastic coil 104 can be attached a cable 118, such as a wireline (e.g., to supply electrical power and communication to the BHA 106), and/or an inner tube for fluid circulation. These different elements can be placed in various order from bottom to top. The BHA 106 may in some instances be attached to other type of cable that supply power and/or be attached to a cable that does not supply power, in which case the BHA 106 may include a battery. Examples of other types of cable include slicklines, for instance. The BHA 106 may be supported adjacent a lower end of the cable 118.
[0040]In a second phase shown at (B) in
[0041]During Phase 3 shown at (C) of
[0042]During Phase 4 shown at (D) of
[0043]
[0044]
[0045]Any type of circuit may be installed in the wellbores drilled as per the current disclosure. One function of the closed loop system 300 is to create the maximum length of contact between the closed loop 328 and the ground to enable heat transfer. In a “heating mode,” a cold fluid is circulated in the closed loop to extract calories from the surrounding hotter rock via conduction. This is schematized in
[0046]A well may be constructed according to various techniques for drilling (rotary drilling, hammer drilling, with air, with mud, etc.), various types of completions (single u-tube, double u-tube, co-axial, etc.), and various cementing types and techniques. The selection of the technique may depend on factors pertaining to available equipment, geology (for example, the techniques are different on hard grounds such as granite/quartz or soft unconsolidated grounds), local regulation, etc. In the shallow geothermal industry, well construction is often handled by geothermal drillers that are typically responsible to: a) drill the wells; b) install the plastic completion; and c) cement the completion in place. Drillers typically operate these 3 steps under the guidance of regulatory norms to guarantee the quality, safety and environmental quality of the installed geothermal probes.
[0047]From an economical perspective, installing these probes is often expressed in terms of total cost/currency per unit of distance (e.g., dollars per meter, euros per meter). The technical-economic efficiency of the geothermal heat exchanger can be expressed in currency per unit of power (e.g., dollars per watt, euros per watt, etc.). For example, for a system having a cost of 80 dollars per meter and a power extraction capability of 50 W/m, a ratio of the two values provides an average cost of 1.6 dollars per watt. The system and method of this disclosure aids in reducing the technical-economic efficiency.
[0048]In some cost analyses of standard geothermal drilling in unconsolidated (soft sedimentary) formations, approximately 50% of cost may be attributable to the drilling operation itself, approximately 25% may be attributable to the probe installation, and approximately 25% may be attributable to the cement operation.
[0049]Among other things, the system and method of this disclosure may reduce cost in a few ways. First, the system and method may reduce “drilling time.” In unconsolidated formations, standard drilling involves drilling with a dual string configuration, a cross-sectional view of which is shown at (A) of
[0050]Second, the system and method may reduce the number of people required for the operation. In conventional drilling, additional operators (perhaps three or four operators) are present on a surface, including a lead driller and typically two or three helpers whose main task is to handle the drilling rod feeding (which is a mostly manual operation). On the contrary, the system and method of this disclosure requires no (or very little) pipe handling as the coil progresses via an automated roll feed of the continuous pipe. Accordingly, the number of personnel can be reduced by a factor of between two to three.
[0051]Third, the system and method may reduce the drilling diameter (bit diameter). For drilling unconsolidated formations, one technique involves drilling with two concentric rod strings, which implies a larger than required drilling diameter. An annular string (often referred to as a “casing”) is positioned around an inner string (often referred to as a “drill rod”). The casing is left in hole while the geothermal probes are lowered and removed before cementing. The casing is used to prevent the hole from collapsing and closing. The coil tube (CT) system and method of this disclosure shown at (B) of
[0052]In the example shown in
[0053]The inner tube 422 is shown at (B) of
[0054]Reducing the bit diameter has several additional advantages: (a) the total amount of earth volume that is drilled is reduced (in the example of
[0055]In some applications, an economic analysis shows that the system and method of this disclosure may reduce the cost of drilling by a factor 5. As shown in
[0056]
[0057]During a step shown at (B) of
[0058]At another step shown at (C) of
[0059]Although certain aspects have been described with reference to certain examples, it is to be recognized that variations and modifications exist within the spirit and scope of one or more independent aspects. Various features and aspects are set forth in the following claims.
Claims
1. A method for installing a well for a borehole heat exchanger, the method comprising:
drilling a hole formation to a predetermined depth relative to a ground surface, drilling the hole formation including operating a bottom hole assembly (BHA) including a drill bit supported at a bottom end of a cable, such as a wireline, the cable positioned within a flexible tube; and
after drilling the hole formation to the predetermined depth, retracting the BHA through the flexible tube to remove the BHA from the hole formation while the flexible tube remains in the hole formation.
2. The method of
3. The method of
4. The method of
5. The method of
6. The method of
7. The method of
the method further comprising, after drilling the hole formation to the predetermined depth and prior to retracting the BHA, moving the reamer to a collapsed state in which the outer diameter of the reamer is smaller than the diameter of the flexible tube.
8. A system for installing a well for a ground source heat pump application, the system comprising:
a cable, such as a wireline, having a lower end;
a bottom hole assembly (BHA) supported adjacent the lower end of the cable, the BHA including a drill bit operable to excavate a hole; and
a flexible tube extending around the cable, the lower end of the flexible tube being removably coupled to the BHA, wherein, while the flexible tube is coupled to the BHA, the flexible tube is movable with the BHA as the drill bit excavates the hole, and, while the flexible tube is uncoupled from the BHA, the flexible tube remains within the hole as the BHA is removed from the hole.
9. The system of
10. The system of
11. The system of
12. The system of
13. The system of
14. The system of
15. The system of
16. The system of
17. A borehole heat exchanger system comprising:
an outer tube positioned within a drilled hole formation, the outer tube comprising a flexible thermoplastic material;
an inner tube positioned within the outer tube to form a coaxial configuration; and
a closed loop circuit formed between the outer tube and the inner tube configured to circulate heat transfer fluid between a ground source heat pump and the drilled hole formation.
18. The borehole heat exchanger system of
19. The borehole heat exchanger system of
20. The borehole heat exchanger system of