The present technology pertains to downhole gas generation, and more specifically to downhole gas generation to provide a pressure reservoir or a pressure-on-demand system.
Hydraulic and pneumatic power systems have both proven to be extremely popular in not only downhole and sub-surface environments, but in the wider world as well, as these systems can be utilized for end-to-end power generation, control, and transmission. The popularity of hydraulic and pneumatic power systems stems at least in part from factors such as their easy and accurate control, their simple and economical design and maintenance requirements, their efficient force multiplication, and their ability to provide constant force and/or torque. The systems differ primarily in their choice of working fluid—hydraulic systems utilize a fluid such as an oil or a specially designed hydraulic fluid, whereas pneumatic systems utilize a gas such as ambient air or nitrogen. Hydraulic systems are known for their ability to transfer very large amounts of power through small diameter tubes and hoses, while pneumatic systems are known for their extremely fast response times.
A number of existing downhole and borehole tools are designed to run on hydraulic or pneumatic power, or can otherwise be converted to run on hydraulic or pneumatic power. However, these tools are almost always powered from the surface, as typically large combustion engines are used to charge the accumulator(s) of the hydraulic or pneumatic system. When powering from the surface, the hydraulic or pneumatic lines may need to stretch for long distances in order to reach a tool at the bottom of a deep borehole, or become subject to snapping or other damage when passing through an area of adverse environmental conditions, both of which can reduce not only the efficiency of the hydraulic or pneumatic system, but can also reduce the viability of using such a system in the downhole environment.
In order to describe the manner in which the above-recited and other advantages and features of the disclosure can be obtained, a more particular description of the principles briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only exemplary embodiments of the disclosure and are not therefore to be considered to be limiting of its scope, the principles herein are described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Various embodiments of the disclosure are discussed in detail below. While specific implementations are discussed, it should be understood that this is done for illustration purposes only. A person skilled in the relevant art will recognize that other components and configurations may be used without parting from the spirit and scope of the disclosure. Additional features and advantages of the disclosure will be set forth in the description which follows, and in part will be obvious from the description, or can be learned by practice of the herein disclosed principles. The features and advantages of the disclosure can be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the disclosure will become more fully apparent from the following description and appended claims, or can be learned by the practice of the principles set forth herein.
It should be understood at the outset that although illustrative implementations of one or more embodiments are illustrated below, the disclosed apparatus and methods may be implemented using any number of techniques. The disclosure should in no way be limited to the illustrative implementations, drawings, and techniques illustrated herein, but may be modified within the scope of the appended claims along with their full scope of equivalents.
Disclosed herein is a downhole chemical reactor which is capable of generating one or more gases for providing pressure-on-demand or filling and maintaining a constant pressure reservoir. The downhole chemical reactor can be placed in a wellbore or other downhole environment for purposes of in-situ gas generation, and the resultant pressure from the generated gas can be used to drive one or more hydraulic or pneumatic tools, which may be located in the same wellbore or downhole environment as the chemical reactor. One or more desired reactants are contained within an inner chamber of the chemical reactor, where the reactants are selected such that they react with one or more well fluids (such as the well brine surrounding the downhole chemical reactor) to generate the one or more gases. Different reactor control mechanisms or reactor controllers can be employed in order to flood the downhole chemical reactor with a suitable amount of fluid for the reaction, as will be explained in greater depth below. In general, the different reactor control mechanisms or reactor controllers can be differentiated as passive or active, and/or can be differentiated on the basis of whether or not they configure the downhole reactor to provide a pressure-on-demand system or a constant pressure reservoir system.
While
As depicted in
As depicted in
In many scenarios, it can be desirable to couple a hydraulic or pneumatic power system to one or more components within wellbore 114, and in particular, to one or more components of the tubular strings (e.g. wellbore tubular 120) positioned within wellbore 114. For example, a pneumatic power system can be used to inflate one or more of the packer assemblies 200a-200d, and a hydraulic power system can be used to control, operate, or otherwise actuate one or more of the downhole tools 300a-300d. In either use case, conventional hydraulic and pneumatic power systems will rely upon one or more large and high-powered mechanical pumps or compressors to generate and apply the requisite pressure to the working fluid of the system. However, these mechanical pumps and compressors (and their corresponding support infrastructure and maintenance requirements) are often times impractical or even impossible to implement in challenging or changing environments such as those associated with subsea formations and subsea wellbores, and are too large to be physically installed downhole, meaning that subsea oil and gas operations will often forego their use. Accordingly, as disclosed herein, it would be highly desirable to provide a downhole chemical reactor for creating hydraulic or pneumatic pressure, either on demand or within a charged accumulator, without using a mechanical or electrical pump.
As mentioned previously,
In
As well brine flows in and fills the inner chamber of downhole chemical reactor 240, the well brine begins to react with at least a portion of reactant 242. In some embodiments, reactant 242 might comprise a single chemical compound, or might comprise a mixture of various different chemical compounds, each of which will react with a different well fluid or will react for a given set of reactor conditions. In this manner, downhole chemical reactor 240 can generate gas for a wider range of well fluids and can do so in a wider range of downhole conditions. In some embodiments, reactant 242 can comprise one or more of a magnesium alloy or an aluminum alloy, which react with well brine to generate hydrogen gas. In some embodiments, reactant 242 can comprise calcium, which reacts to produce calcium hydroxide and hydrogen. In some embodiments, reactant 242 can comprise zinc and the well fluid is an acid used in a wellbore cleanup operation, the two of which will react to generate hydrogen gas. More generally, it is contemplated that reactant 242 can comprise one or more metals, which will react to form a metal oxide, which then further reacts to produce a metal hydroxide and hydrogen gas. In some embodiments, rather than selecting reactants 242 to generate hydrogen gas, reactants 242 can be selected to react with the well fluid to generate carbon dioxide.
In some embodiments, the volume of the inner chamber of downhole chemical reactor 240, and therefore the volume of well brine that floods the reactor, can far exceed the volume of fluid required to react with reactant 242 to generate sufficient gas to reach the maximum pressurization defined by relief valve 244. For example, downhole chemical reactor 240 might have a volume of about 38 liters (L) (about 10 gallons) when only about 236 milliliters (ml) (about 1 cup) of water is required for the gas generation reaction, although of course other reactor volumes and minimum fluid requirements are possible without departing from the scope of the present disclosure. Nevertheless, regardless of the precise ratio between the reactor volume and volume of fluid required, it is very frequently the case that excess fluid will be present within the inner chamber of downhole chemical reactor 240. However, downhole chemical reactor 240 is self-regulating to stabilize at its maximum pressure and expel any excess fluid before it can react further and waste any significant amount of reactant 242, as will be explained below.
As the well brine reacts with reactant 242 and gas is generated, the internal pressure of downhole chemical reactor 240 increases, as the newly generated gas is unable to exit through the one-way check valve 226 and is, as of yet, insufficiently pressurized to open relief valve 244, which for example may have an opening pressure of 1000 psi. Accordingly, the downhole chemical reactor 240 will continue to increase in pressurization until either an insufficient quantity of raw material (e.g. well brine or reactant 242) remains or until its internal pressure reaches the maximum defined by relief valve 244. As seen in
Thus, as mentioned above, downhole chemical reactor 240 is self-regulating via the relief valve 244—relief valve 244 may open a first time to expel, for example, half of the well fluid contained within downhole chemical reactor 240 before closing, at which point the gas generation reaction will raise the interior pressure of the reactor until relief valve 244 opens once again to expel an additional portion of the remaining half of the well fluid contained within the reactor. This process will continue until there is no well fluid left. The set pressure of the relief valve sets the maximum pressure differential that the downhole chemical reactor 240 may achieve above the well pressure. If this maximum pressure differential is ever exceeded, then relief valve 244 will act to expel any excess pressure and any excess well fluid to ensure that any wastage of reactant 242 is minimized. Thus, in this manner relief valve 244 is coupled to the inner pressure chamber of downhole chemical reactor 240 in order to act as a pressure regulator to control a maximum pressurization of the inner pressure chamber. Such a functionality is particularly useful in permanent installations where it is not contemplated that downhole chemical reactor 240 will ever be removed for servicing or replenishment of its supply of reactant 242.
However, the design of downhole chemical reactor 240 as depicted is not self-replenishing, as it possesses no mechanism to re-flood its inner chamber an initiate additional gas generation reactions to re-pressurize itself. In other words, downhole chemical reactor 240 is shown as a one-time use reactor—its 1100 psi charged volume can be used to perform work until being reduced to the 90 psi equilibrium pressure (described above as being based upon the external well pressure and the cracking point of check valve 226), at which point downhole chemical reactor 240 is in a fully depleted state.
Accordingly,
In some embodiments, downhole chemical reactor 340 can be identical to previously described downhole chemical reactor 240, with the exception of this different reactor controller described above. In particular,
When it is determined that a pressure source is needed downhole, such as to power a packer assemblies 200 or downhole tool 300, e.g. to inflate a packer, move a sleeve, power a downhole tool, open a valve, move a piston etc., a command can be received to open both the upper valve 326a and the lower valve 326b. These valves can be electrically controlled, mechanically controlled, hydraulically controlled, or controlled via any other known valve control mechanism, and as mentioned previously, it is contemplated that these valves are controlled in response to one or more commands received from the surface. In some embodiments, a small downhole battery might be present (or combined with the downhole chemical reactor), such that only control commands need be received from the surface, leaving the downhole tool(s) and/or borehole assembly fully self-powered, with the downhole battery providing electrical needs for low to moderate power applications and the downhole chemical reactor providing hydraulic/pneumatic needs for high power applications. In some embodiments, the downhole battery can be supplemented with or replaced by electrical supply lines from the surface, which might also carry wireline or other communications and commands, although in such embodiments the downhole chemical reactor remains better suited for high power hydraulic and pneumatic applications, as even surface electrical power supply may be insufficient.
Returning now to the discussion of the upper valve 326a and the lower valve 326b, with both valves open, any excess gas (e.g. generated in a previous cycle that did not fully empty the reactor) within the inner chamber of downhole chemical reactor 340 is vented until the reactor pressure reaches equilibrium with the well pressure. This excess gas vents from upper valve 326a. Once this equilibrium is reached, a volume of well fluid enters downhole chemical reactor 340 from the bottom, via lower valve 326b, while a corresponding volume of gas is displaced through upper valve 326a.
Upper valve 326a and lower valve 326b are then closed, allowing pressure to build within downhole chemical reactor 340 as was described above with respect to
In some embodiments, rather than using a discrete upper valve 326a and lower valve 326b to provide the reactor controller, a single large-diameter inlet valve could be used as the reactor controller, where its diameter is large enough to permit the simultaneous ingress of well fluid and egress of gas from the downhole chemical reactor 340. An advantage of using a single large-diameter inlet valve as the reactor controller is that there is no need for coordinating the open and close timings like there is with the upper valve 326a and lower valve 326b, which should operate in substantially synchronous fashion in order to minimize unexpected or undesirable movements of well fluid and reactor gas. However, the single large-diameter inlet valve is generally unable to selectively vent either gas or well fluid, as is possible with the upper valve 326a and lower valve 326b, as the inlet to the single large-diameter valve on the interior of downhole chemical reactor 340 will almost always be fully covered by the well fluid (if the single valve is located towards the bottom portion of the reactor) or fully covered by the reactor gas (if the single valve is located towards the upper portion of the reactor).
A check valve 356 is interposed between the output of downhole pump 350 and the inlet of downhole chemical reactor 340, shown here as having a cracking pressure of 10 psi. Here, the primary purpose of check valve 356 is to provide a one-way flow such that well fluid may be pumped into the downhole chemical reactor 340 by the pump 350, but gas cannot flow out of the reactor via this same path. As such, check valve 356 can more generally be selected to have a cracking pressure sufficiently low that pump 350 need not be high-powered.
In operation, pump 350 functions as the reactor controller by moving a desired volume of well fluid from the wellbore and into the inner pressure chamber of downhole chemical reactor 340, which causes the reactor to become pressurized by the gas generation reaction of the well fluid with reactant 342. The amount of well fluid pumped into the inner chamber of downhole chemical reactor 340 can many times be more precisely metered via pump 350 than it can be when using either the upper and lower inlet valves 326a,b or the singe large-diameter inlet valve. Additionally, pump 350 may be sufficiently powerful to pump against a pressure gradient such that well fluid may be pumped into downhole chemical reactor 340 even when the reactor is partially pressurized, which was not necessarily possible in either of the inlet valve configurations discussed above. As such, downhole chemical reactor 340 in this pump-driven configuration is not associated with a minimum or equilibrium pressure that depends strictly upon the external well pressure surrounding the reactor, although it is noted that the maximum pressure as shown does still depend upon a combination of the external well pressure and the set point of the pressure regulator comprising relief valve 344.
Instead, downhole chemical reactor 340 can have a minimum pressure that is controllable or adjustable via pump 350. For example, assuming that pump 350 is sufficiently powerful, it can be configured to pump in some additional volume of well fluid every time downhole chemical reactor 340 falls below a desired minimum pressurization, e.g. trigger pump 350 when the reactor pressure falls below 250 psi. Advantageously, this can maintain a more reliable source of pressure by avoiding a state where the downhole chemical reactor 240 reaches equilibrium with the pressure of the surrounding well. However, such a configuration is more power intensive, requires relatively frequent operation of pump 350, and can require a much larger and more powerful pump 350 than is feasible in the downhole environment. Indeed, operation of pump 350 in the manner described above effectively causes it to function in a manner similar to conventional surface hydraulic or pneumatic systems, which constantly run one or more pumps to maintain a pressure reservoir.
Accordingly, it would be desirable to provide a downhole chemical reactor with a pumping system capable of leveraging natural variations within the wellbore or downhole environment to thereby maintain the downhole chemical reactor as a constant pressure reservoir without requiring an electrical or similar mechanical pump.
For the sake of illustration and consistency with prior examples, downhole chemical reactor 440 is depicted as experiencing the same external well pressure of 100 psi and as having the same 1000 psi set point for its pressure regulator relief valve 444, although it is appreciated that one or both of these parameters could vary or otherwise be adjusted without departing from the scope of the present disclosure.
As illustrated, the reactor controller provided by phase change pump system 400 comprises a first phase change pump 402 having a melting point of 290° F., a second phase change pump 404 having a material with a melting point of 300° F., and a third phase change pump 406 having a material with a melting point of 310° F., although other numbers of melting points are possible without departing from the scope of the present disclosure. The phase change pumps 402, 404, 406 each have an inlet with a check valve 412a, 414a, 414c, respectively, and each have an outlet with a check valve 412b, 414b, 416c, respectively. The inlets draw from the well fluid in the downhole environment and the outlets discharge into the downhole chemical reactor 440. As shown here, all six of the check valves have the same 10 psi cracking pressure, although the choice of cracking pressure can be chosen to better match the individual pumping characteristics of each phase change pump and/or the expected downhole conditions and temperature variations.
In operation, thermal variations within the downhole environment will cause the phase change pumps 402-406 to variously and intermittently go through melting and solidifying cycles, which leverages the volume change associated with this change of state to drive the pumping action of the overall phase change pump system 400. In particular, the phase change pumps 402-406 are can be configured such that they experience a 10-20 percent change in volume when going from solid to liquid, and vice versa. For instance, the volume change may be in an increase in volume when heated (melting) and a decrease in volume when cooled (solidifying).
The phase change material, such as wax, located on the left-hand side of each phase change pump in a phase change compartment separated from a fluid compartment on the right-hand side of the phase change pump. The phase change compartment and fluid compartment are separated by by a membrane, piston, or other moveable partition that effectively seals the two compartments to prevent intermingling of the phase change material and well fluid. When the phase change material solidifies, it reduces in volume and causes the phase change material compartment to contract. The fluid compartment undergoes a corresponding expansion, which allows well fluid to overcome the cracking pressure of the check valve on the inlet of the phase change pump and then flow into the fluid compartment to occupy the newly expanded volume. When the phase change material melts, it increases in volume and causes the phase change compartment to expand. The fluid compartment undergoes a corresponding contraction, which forces a portion of the well fluid contained within the fluid compartment to be discharged through the outlet of the phase change pump.
The outlets of the three phase change pumps 402-406, after passing through their respective check valves 412c-416c, are connected by a common conduit, seen in
As long as the pressure of downhole chemical reactor 440 exceeds 990 psi, then phase change pumps 402-406 will circulate well fluid indefinitely, as any amount of well fluid discharged into the common conduit via the phase change pump outlets will cause a corresponding discharge via the relief valve 424. However, once the pressure of downhole chemical reactor 440 falls below 990 psi, for example because some or all of the gas within the reactor is utilized to perform work, it then becomes easier for the common conduit to discharge well fluid into the reactor via check valve 426 than to discharge into the wellbore via relief valve 424. Note that this process can occur even as pressure from downhole chemical reactor 440 is actively being used, meaning that the reactor can be recharged in substantially real-time.
The discharge of well fluid into downhole chemical reactor 440 may be small, but recall that only a small volume of well fluid is required to react with reactant 442 to generate a large amount of gas within the downhole chemical reactor. Accordingly, downhole chemical reactor 440 will be re-pressurized to somewhere between 990 psi (its minimum pressure) and 1100 psi (its maximum pressure before the 1000 psi relief valve 444 is triggered). Downhole chemical reactor 440 then lays dormant, with the phase change pump system 400 discharging well fluid via the 900 psi relief valve 424, until the pressure source of the downhole chemical reactor is called upon again to perform work. Downhole chemical reactor will then fall below 990 psi and the refilling cycle repeats to recharge the reactor once again, thereby providing the desired constant pressure source in the downhole environment.
Advantageously, phase change pump system 400 and downhole chemical reactor 440 can provide a constant pressure source in the downhole environment entirely without the use of electricity or a conventional mechanical pump. The phase change pump system 400 is self-sustaining and draws energy wholly from the thermal fluctuation in the surrounding downhole environment, allowing downhole chemical reactor to function in a self-contained and standalone fashion nearly indefinitely, limited only by the exhaustion of the supply of reactant 442 or by the lack of sufficient thermal gradients to drive the phase change pump system 400.
However, it is rarely the cause that the wellbore or downhole environment remains thermally static, as temperature changes can happen often and for a variety of different reasons. For example, temperature changes will very frequently be strongly associated with one or more areas where fluid is being injected. The fluid injection itself tends to cool the wellbore environment, meaning that a greater injection rate will typically be associated with a colder temperature. Similarly, the temperature of the injected fluid can be a driving factor, most notably when comparing the far colder injected fluid temperatures associated with injecting at night rather than during the day. Even if the fluid is heated at the surface prior to injection (e.g. steam injection) a temperature variation between night and day will be observed, or a rate-based temperature variation will be observed. As a still further example, fluid injection might be cycled with intervals of producing from the wellbore, which can in many cases lead to rather large temperature variations. The production rate can also lead to temperature variation, as the produced fluid is typically coming from a lower (hotter) location in the wellbore, meaning that a reduced production rate will lead to a cooler wellbore temperature than an increased production rate. Closing off or shutting in the well can additionally lead to temperature variations, and indeed, any of the temperature variations described above (which can occur either naturally within the well or as a consequence of planned operations within the well) can be intentionally induced in order to drive the phase change pump system 400 in a desired fashion. For example, if it is observed that the downhole chemical reactor 440 needs to be re-pressurized but the wellbore temperature is too low to drive phase change pump system 400, then steam could be injected from the surface or the injection rate could be reduced with the intention of raising the ambient downhole temperature in order to drive one or more cycles of the phase change pump system 400.
When the wellbore temperature is relatively cool, then well fluid flows into the pressure accumulator system via check valve 512 on the inlet of pressure accumulator 502. When the wellbore temperature is relatively hot, then well fluid flows out of the pressure accumulator system 500 and into an intermediate coupling between third pressure accumulator 506 and the downhole chemical reactor 540. Similar to the phase change pump system 400 of
Similar to the downhole chemical reactor 440 of
In some embodiments, the pressure accumulator system 500 can be provided as a single pressure accumulator volume, rather than the three pressure accumulators 502-506 that are shown. However, by varying the check valve values between the three pressure accumulators (i.e. 10 psi check valve 512 on the input to first pressure accumulator 502; 300 psi check valve 514 on the input to second pressure accumulator 504; 600 psi check valve on the input to third pressure accumulator 506), the pressure accumulator system 500 as a whole is more efficient and better able to convert small temperature changes into a pumped output.
In addition to temperature variations, pressure accumulator system 500 can also be driven by pressure variations within the wellbore environment. In some embodiments, pressure accumulator system 500 can be isolated from the downhole chemical reactor 540, such that they are not necessarily exposed to the same external pressure. For example, pressure accumulator system 500 could be located in the annulus of the wellbore and downhole chemical reactor 540 could be located in the section of the wellbore. In this manner, pressure accumulator system 500 could more easily be exposed to pressure changes to drive its pumping action, while downhole chemical reactor 540 stays relatively isolated from any changes. Additionally, active means can be taken from the surface to drive the pressure accumulator system 500 for example by shutting in the well or by pumping into the annulus to increase its pressure specifically to force additional well fluid through the pressure accumulators 502-506 and into the downhole chemical reactor 540 until the reactor has been sufficiently re-pressurized.
For clarity of explanation, in some instances the present technology may be presented as including individual functional blocks including functional blocks comprising devices, device components, steps or routines in a method embodied in software, or combinations of hardware and software.
Methods according to the above-described examples can be implemented using computer-executable instructions that are stored or otherwise available from computer readable media. Such instructions can comprise, for example, instructions and data which cause or otherwise configure a general purpose computer, special purpose computer, or special purpose processing device to perform a certain function or group of functions. Portions of computer resources used can be accessible over a network. The computer executable instructions may be, for example, binaries, intermediate format instructions such as assembly language, firmware, or source code. Examples of computer-readable media that may be used to store instructions, information used, and/or information created during methods according to described examples include magnetic or optical disks, flash memory, USB devices provided with non-volatile memory, networked storage devices, and so on.
Devices implementing methods according to these disclosures can comprise hardware, firmware and/or software, and can take any of a variety of form factors. Typical examples of such form factors include laptops, smart phones, small form factor personal computers, personal digital assistants, rackmount devices, standalone devices, and so on. Functionality described herein also can be embodied in peripherals or add-in cards. Such functionality can also be implemented on a circuit board among different chips or different processes executing in a single device, by way of further example.
The instructions, media for conveying such instructions, computing resources for executing them, and other structures for supporting such computing resources are means for providing the functions described in these disclosures.
Although a variety of examples and other information was used to explain aspects within the scope of the appended claims, no limitation of the claims should be implied based on particular features or arrangements in such examples, as one of ordinary skill would be able to use these examples to derive a wide variety of implementations. Further and although some subject matter may have been described in language specific to examples of structural features and/or method steps, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to these described features or acts. For example, such functionality can be distributed differently or performed in components other than those identified herein. Rather, the described features and steps are disclosed as examples of components of systems and methods within the scope of the appended claims. Moreover, claim language reciting “at least one of” a set indicates that one member of the set or multiple members of the set satisfy the claim.
Numerous examples are provided herein to enhance understanding of the present disclosure. A specific set of statements are provided as follows.
Statement 1: A downhole pressure generation system comprising: a chemical reactor having an inner pressure chamber, wherein the chemical reactor is located within a wellbore; a chemical reactant disposed within the inner pressure chamber, wherein the chemical reactant is reactive with at least a first fluid to generate one or more gases to pressurize the inner pressure chamber of the chemical reactor; a reactor controller coupled to an inlet of the inner pressure chamber in order to permit well fluid to flow from the wellbore and into the inner pressure chamber, wherein the well fluid contains at least the first fluid; and a pressure regulator coupled to the inner pressure chamber in order to control a maximum pressurization of the inner pressure chamber.
Statement 2: The downhole pressure generation system of statement 1, wherein the reactor controller comprises one or more pumps, each pump comprising a phase change compartment and a fluid compartment divided by a movable partition, such that: a temperature decrease in the wellbore causes the well fluid to flow into an inlet of the fluid compartment in response to a material in the phase change compartment solidifying, where the material solidifying reduces the volume of the phase change compartment and increases the volume of the fluid compartment; and a temperature increase in the wellbore causes the well fluid to discharge from an outlet of the fluid compartment and flow into the inner pressure chamber in response to the material in the phase change compartment melting, where the material melting increases the volume of the phase change compartment and decreases the volume of the fluid compartment.
Statement 3: The downhole pressure generation system of statement 1 or 2, wherein the reactor controller further comprises: a common conduit connected to the outlet of each phase change pump and the inlet of the inner pressure chamber, such that well fluid received within the common conduit will discharge into the inlet of the inner pressure chamber if a pressure within the common conduit is greater than a pressure within the inner pressure chamber; and a pressure relief valve disposed on the common conduit before the inlet of the inner pressure chamber, such that well fluid received within the common conduit will discharge through the pressure relief valve and into the wellbore if the pressure within the common conduit exceeds a set pressure of the pressure relief valve.
Statement 4: The downhole pressure generation system of statement 3, wherein the material in the phase change compartment is a wax.
Statement 5: The downhole pressure generation system of statement 4, wherein the material comprises an aliphatic hydrocarbon having a melting point of at least 200° F.
Statement 6: The downhole pressure generation system of any one of the preceding statements 1-5, wherein the reactor controller comprises two or more pressure accumulator stages, wherein: well fluid flows from the wellbore and into a first pressure accumulator stage via a first inlet having a first check valve; well fluid flows from a first outlet of the first pressure accumulator stage to a second inlet of a second pressure accumulator stage, wherein the first outlet and second inlet are connected by a second check valve having a greater cracking pressure than the first check valve; and well fluid flows from a second outlet of the second pressure accumulator stage and into the inner pressure chamber of the chemical reactor.
Statement 7: The downhole pressure generation system of any one of the preceding statements 1-6 wherein the reactor controller further comprises: an intermediate coupling connected to an outlet of a final one of the two or more pressure accumulator stages and to an inlet of the inner pressure chamber, such that well fluid received within the intermediate coupling from the final one of the two or more pressure accumulator stages will discharge into the inlet of the inner pressure chamber if a pressure within the intermediate coupling is greater than a pressure within the inner pressure chamber; and a pressure relief valve disposed on the intermediate coupling before the inlet of the inner pressure chamber, such that well fluid received within the intermediate coupling will discharge through the pressure relief valve and into the wellbore if the pressure within the common conduit exceeds a set pressure of the pressure relief valve.
Statement 8: The downhole pressure generation system of any one of the preceding statements 1-7, wherein the reactor controller comprises a check valve configured to open the inlet of the inner pressure chamber when a pressure of the wellbore exceeds a pre-determined cracking pressure of the check valve.
Statement 9: The downhole pressure generation system of any one of the preceding statements 1-8, wherein the reactor controller comprises: a first valve coupled to an upper portion of the inner pressure chamber; and a second valve coupled to a lower portion of the inner pressure chamber; wherein opening the first valve and the second valve causes gas to discharge from the inner pressure chamber via the first valve until a pressure of the inner pressure chamber is substantially equal to a pressure of the wellbore and causes well fluid to flow from the wellbore and into the inner pressure chamber via the second valve.
Statement 10: The downhole pressure generation system of any one of the preceding statements 1-9, wherein the reactor controller comprises a large-diameter valve coupled to the inner pressure chamber such that opening the large-diameter valve: causes gas to discharge from the inner pressure chamber via a first portion of the large-diameter valve until a pressure of the inner pressure chamber is substantially equal to a pressure of the wellbore; and causes well fluid to flow from the wellbore and into the inner pressure chamber via a second portion of the large-diameter valve.
Statement 11: The downhole pressure generation system of any one of the preceding statements 1-10, wherein the reactor controller comprises a pump located within the wellbore, the pump having an inlet for the uptake of well fluid from the wellbore and an outlet for the discharge of the well fluid into the inlet of the inner pressure chamber.
Statement 12: The downhole pressure generation system of statement 11, wherein the pump is an electrical pump.
Statement 13: The downhole pressure generation system of statement 12, further comprising: a downhole battery, the battery electrically coupled to power at least the electrical pump; and a receiver operable to receive one or more control commands and adjust the operation of the electrical pump based at least in part on the one or more control commands.
Statement 14: The downhole pressure generation system of any one of the preceding statements 1-13, wherein the chemical reactant comprises one or more of: a magnesium alloy, an aluminum alloy, a zinc alloy, calcium, and a metal hydroxide.
Statement 15: The downhole pressure generation system of any one of the preceding statements 1-14, wherein the one or more generated gases comprise one or more of hydrogen and carbon dioxide.
Statement 16: The downhole pressure generation system of any one of the preceding statements 1-15, wherein the pressure regulator coupled to the inner pressure chamber comprises a pressure relief valve and the maximum pressurization of the inner pressure chamber is based on at least a set pressure of the pressure relief valve and a pressure of the wellbore.
Statement 17: The downhole pressure generation system of statement 16, wherein the pressure relief valve is configured to automatically discharge at least well fluid from the inner pressure chamber in response to the maximum pressurization of the inner pressure chamber being exceeded.
Statement 18: The downhole pressure generation system of statement 17, wherein the pressure relief valve is located beneath the inner pressure chamber such that the well fluid from the inner pressure chamber discharges before any generated gas within the inner pressure chamber.
The present application is a divisional of U.S. application Ser. No. 16/615,698, filed Nov. 21, 2019, which claims benefit to international Application No. PCT/US2019/012752 filed Jan. 8, 2019, which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
Parent | 16615698 | Nov 2019 | US |
Child | 17738201 | US |