Patent Grant
11808102
The present invention relates to a dissolvable frac plug housing a tracer compound that can be identified from water or other wellbore fluids when the plug is to be dissolved or removed from the wellbore.
Downhole plugs are used in the extraction industry to seal off portions of wellbores for a variety of reasons. Portions of a wellbore may be sealed off to assist in the collection of hydrocarbons, to create pressure, or isolate zones of the well, for example. After the operation involving the downhole plug is complete, the plug must be removed from the wellbore or otherwise disposed of. Typically, dissolvable plugs are made in part or whole of material that dissolves the plugs when they come into contact with certain elements such as water or other wellbore fluids. After the plug is sufficiently dissolved, its remnants may be more easily retrieved for disposal.
Various means of identifying dissolved downhole plugs have been practiced over the years. Traditionally, an operator pumps tracers into the completion fluid at each stage during the frac operation. Such operations, however, can be complex, time-consuming, and expensive.
Housing tracer materials in dissolvable plugs has been hereby proposed to remedy the disadvantages of traditional methods and facilitate identification of plugs that do not produce. The simplicity of housing tracer materials in dissolvable plugs allows real-time data analysis without any change to typical frac operations. For example, in a plug and perf well, the well typically has around 35 to 50 fracturing stages, which means there would be around 35 to 50 frac plugs set inside the well at different depths. Therefore, with the traditional method, it would be practically difficult for the end user to pump tracers into the completion fluid for multiple fracturing stages.
There is, therefore, a need for a dissolvable frac plug that can update the status of dissolution of plugs for each fracturing stage without the operator from location that normally mixes tracers with the completion fluid during pumping operations. In particular, there is a need for dissolvable frac plugs that impregnate different kinds of tracer materials during the frac job and release and expose them to water or other wellbore fluids once the plugs dissolve. There is a further need for tracer materials that can readily make chemical change in the fluids.
According to embodiments of the present invention, a dissolvable frac plug is disclosed. The dissolvable frac plug comprises one or a plurality of internal chambers surrounded by an external wall with at least one chamber containing a tracer compound in an amount sufficient to be observed from water or other wellbore fluids when the tracer compound is released to the fluids. As a portion or portions of the external wall dissolve due to contact with water or other wellbore fluids, the tracer compound is released to the fluids and flows back to land surface so that the end user on the surface can monitor the status of dissolution of plugs for each fracturing stage.
Preferably, one or a plurality of internal chambers are provided, at least one, some or all of which further contain a dry powder. Alternatively, one or some of the chambers contain the dry powder and one or some of the chambers contain one or more different chemical components that combine with the powder to create a corrosive solution or environment.
In some embodiments, the internal chamber includes one or more cylindrical chambers that surround the dissolvable frac plug. These can be arranged in a variety of configurations with the size of chambers varying depending upon the size of the plug and the speed of dissolution desired, as well as to accommodate the tracer compound.
In certain desirable embodiments, the external wall includes one or more openings to allow filling or packing of the internal chamber with a tracer compound, a dry powder and/or, if present, other components. In some of these embodiments, the one or more openings are closed by a curable compound that seals the internal chamber(s) and prevents escape of the tracer compound, the dry powder and/or the other components.
In a preferred embodiment, the dry powder is sodium bisulfate or aluminum chloride or both and the external wall is made of a dissolvable aluminum or magnesium metal or alloy. Generally, the external wall is configured to dissolve in water or other wellbore fluids within eight and twelve hours, and then the tracer compound is released to water or other wellbore fluids. Plural internal chambers can be provided, one or more of which contain the tracer compound, one or more of which contain a dry powder and one or more of which contain one or more of other chemical components that combine with the powder to create a corrosive environment. The dry powder materials can be provided in the same chamber or in different, adjacent chambers. Placing different dry powders in different chambers is necessary when the dry powders are reactive with each other. In that situation, they can react after being released to create a more corrosive environment that causes dissolution of the plug.
In a preferred embodiment, the tracer compound is in a form of powder, capsule or solution. Tracer compounds are categorized into three groups: oil soluble tracers, water soluble tracers, and gas soluble tracers. Typical oil soluble tracers are halogenated hydrocarbons. The halogenated hydrocarbons may include, but not be limited to, fluorobenzoates, chlorobenzoates and bromobenzenes. Typical water soluble tracers are halogenated salts. The halogenated salts may include, but not be limited to, sulfonic acids, fluorobenzoic acids and chlorobenzoic acids. Typical gas soluble tracers are perfluorinated compounds. The perfluorinated compounds may include, but not be limited to, perfluorinated compounds such as mercaptan, nitrogen, perfluoromethylcyclopentanes and perfluoromethylcyclohexanes.
In some embodiments, multiple dissolvable frac plugs, for example, from 35 to 50 dissolvable frac plugs can be provided, each of the dissolvable plugs containing a different kind of tracer compound to be released to water or other wellbore fluids and flow back to land surface, which allows the end user on the surface to identify which frac plug dissolves and where the flow originates from due to different and unique chemical features of each tracer compound.
An additional embodiment of the present invention includes a method of tracking dissolution of a dissolvable frac plug. The method comprises providing a dissolvable frac plug comprising at least one internal chamber surrounded by an external wall with the chamber containing a tracer compound in an amount sufficient to be observed from water or other wellbore fluids when released to the fluids, delivering the dissolvable frac plug into a wellbore wherein water or other wellbore fluids are present downstream of the plug, initially dissolving the dissolvable frac plug by contact with the water or other wellbore fluids over a certain period of time to at least dissolve a portion or portions of the external wall and expose at least a portion of one or some of the internal chambers, and releasing the tracer compound from the internal chamber into the water or other wellbore fluids; and identifying the released tracer compound from the water or other wellbore fluids.
Various features of examples and embodiments in accordance with the principles described herein may be more readily understood with reference to the following detailed description taken in conjunction with the accompanying drawings, where like reference numerals designate like structural elements, and in which:
The present system and method will be described in connection with the figures, it being understood that the description and figures are for illustrative, non-limiting purposes.
Embodiments of the present invention disclose a dissolvable downhole tool in particular as a frac plug. The dissolvable downhole tool comprises an internal chamber containing one or more tracer compounds to be released to certain downhole fluids such as water or other wellbore fluids and flow back to land surface to update the status of dissolution of the downhole tool to the end user on the surface. The compounds are released in the downhole environment after an external wall of the internal chamber is dissolved from prolonged contact with the downhole fluids.
The dissolvable frac plug 100 may be constructed with a variety of materials. In some embodiments, the dissolvable frac plug may comprise material selected or designed for withstanding downhole conditions. Such material may include insoluble metals or alloys including titanium, copper, iron, and combinations thereof. Suitable metals and alloys may also be blended to other material to impart desirable properties to relevant parts of the dissolvable frac plug 100, such as increased strength or resistance to a certain downhole conditions.
Further, at least part of the dissolvable frac plug 100 is fabricated with material that can dissolve under certain conditions. Such materials may lose structural integrity, disintegrate, and even become soluble over time as they come in contact with or are immersed in other materials or compounds. In particular, the dissolvable frac plug 100, or portion of the dissolvable frac plug 100, may be built with material that reacts with and is degraded by exposure to downhole fluids such as water, brine, injection fluids, production fluids, drilling fluids, or various combinations thereof.
The dissolvable frac plug 100 further comprises an internal chamber 120. In the embodiment illustrated in
The internal chamber 120 serves to impregnate one or more of tracer or dye compounds in an amount (e.g., from about 10 mg to about 50 mg, from about 15 mg to about 45 mg, from about 20 mg to about 40 mg, or from about 25 mg to about 35 mg) sufficient to be observed from water or other wellbore fluids when released to the fluids. The tracer or dye compounds may come in any of a variety of forms. For example, the tracer or dye compounds may be a solid. It can be in a form of powder. In preferred embodiments, tracer compounds are categorized into three groups: oil soluble tracers, water soluble tracers, and gas soluble tracers. Typical oil soluble tracers are halogenated hydrocarbons. The halogenated hydrocarbons may include, but not be limited to, fluorobenzoates, chlorobenzoates and bromobenzenes. Typical water soluble tracers are halogenated salts. The halogenated salts may include, but not be limited to, sulfonic acids, fluorobenzoic acids and chlorobenzoic acids. Typical gas soluble tracers are perfluorinated compounds. The perfluorinated compounds may include, but not be limited to, perfluorinated compounds such as mercaptan, nitrogen, perfluoromethylcyclopentanes and perfluoromethylcyclohexanes. In some embodiments, the tracer or dye compounds may be packaged in a small water soluble pill, packet, pod or bag to separate it from the corrosive compound and, if present, one or more different chemical components. In other embodiments, the tracer compound can be mixed or housed with the corrosive compound and, if present, one or more different chemical components in at least one, some or all of the internal chambers 120. Whether the tracer compound, corrosive compound, and one or more different chemical components are mixed or housed in the same compartment or not, the ratio between the tracer compound and corrosive compound is about 1:1 (less corrosive) to 1:3 (more corrosive). The tracer compound, corrosive compound, and, if present, one or more different chemical compounds can be packaged together in the same pill, packet, pod, or bag without interacting or reacting with each other to affect each compound's performance or activity. In a plug and perf well, a number of frac plugs, for example, from 1 to 85, from 5 to 80, from 10 to 75, from 15 to 70, from 20 to 65, from 25 to 60, from 30 to 55, from 35 to 50, from 40 to 45 frac plugs may set inside the well at different depths, thereby creating multiple fracturing stages. Alternatively, plug and perf wells can have more than 85 plugs or more than 100 plugs per well. Each frag plug 100 is delivered into a wellbore wherein water or other wellbore fluids are present downstream of the plug. Each frac plug 100 may thus hold a different kind of the tracer or dye compound to facilitate identification of each frac plug. Once a portion or portions of the external wall 122 of the frac plug 100 is dissolved by water or other wellbore fluids after a period of time to allow wellbore operations to take place, it will expose the tracer or dye compounds to the downhole environment, including the wellbore fluids. When wellbore fluids containing the tracer or dye compounds flow back to land surface, the end user will be able to monitor the released tracer or dye compounds from the water or other wellbore fluids. The tracer or dye compounds when released to the water or other wellbore fluids can be detected by, for example, analyzing fluid samples and identifying parts per million of the tracer or dye compounds using analyzing instruments. The end user then will be able to identify which frac plug dissolves and where the flow originates from due to different and unique chemical features of each tracer or dye compound. Each and every tracer compound is unique and can be identified through the fluid analysis. It is important to make sure to dissolve each frac plug not to have obstructions in the wellbore. If desired, multiple chambers of each tracer compound or even multiple chambers of different tracer compounds can be used. Each chamber's external wall may have a different size, thickness, composition, or other characteristic, thereby releasing different tracer or dye compounds at different times.
The internal chamber 120 further serves to house a compound that is caustic or corrosive to at least a dissolvable portion of the dissolvable frac plug 100. Herein, the terms “caustic” or “corrosive” as applied to the compound refer to a compound that is able to cause, promote, enhance, or accelerate the dissolution of another substance, whether alone or in combination with other compounds. Thus, the internal chamber 120 is configured to contain a corrosive compound capable of causing or accelerating the disintegration of at least a part of the dissolvable frac plug 100. The corrosive compound may come in any of a variety of forms. The compound may be a solid, liquid, or a gas, or any combination thereof, in various embodiments. Further, the corrosive compound may be able to react with a reactive portion of the dissolvable frac plug 100 by itself. This of course requires the design of the chamber 120 holding the corrosive material to have a sufficient thickness to retain the necessary strength for a period of time to allow wellbore operations to take place (e.g., 8-12 hours) before the plug 100 dissolves sufficiently to facilitate removal. In addition, the design of the internal chamber 120 and in particular, the thickness of the external wall 122 may reflect the possibility that the dissolvable frac plug 100 is immersed in enough water to start the dissolution of the external wall 122, as is the case in a typical wellbore.
Preferably, the corrosive compound is one that requires the addition of a different compound to gain the capability to rapidly degrade or increase the dissolution of the dissolvable frac plug 100. This can be achieved by providing different compounds in adjacent chambers such that the initial dissolution of the external wall 122 causes the compounds to be released where they can mix to form greater corrosivity and faster dissolution of the plug. For example, in some embodiments, one chamber may contain sodium bisulfate while another contains aluminum chloride, the mix of which may be more corrosive than each alone. Alternatively, the existing corrosive properties of a compound can be enhanced when the compound is combined with surrounding wellbore fluids. For example, a salt compound when released from the internal chamber combines with groundwater to form a solution that is much more corrosive than the salt itself. Further, multiple different compounds in different chambers (e.g., the sodium bisulfate, aluminum chloride, and others) may mix together with the downhole fluids to form more potent corrosive solutions to dissolve the plug 100 at a faster rate.
During operation of the dissolvable frac plug 100 in the wellbore, external surfaces of the dissolvable frac plug 100, and in particular, the dissolvable external wall 122 of the internal chamber 120, are exposed to downhole fluids such as water, brine, or injection fluids. The fluids may thus begin to degrade the external wall 122 during the operation of the dissolvable frac plug 100 at a relatively slow rate. In environments such as the Permian basin where downhole conditions may not be sufficiently corrosive, the dissolution of the dissolvable portions of the frag plug 100 may be minimal while the plug is deployed and operational. However, a size, thickness, composition, or other characteristic of the external wall 122 may be designed to time the degradation of the external wall 122 by the downhole fluids with the duration of deployment of the dissolvable plug 100. For example, the external wall may be sized to not be breached until after 8-12 hours to allow time for conventional fracking operations to be conducted. Accordingly, after operations involving the dissolvable frac plug 100 are completed, the downhole fluids breach the external wall 122 and cause the corrosive compound contained in the internal chamber 120 to and mix with the downhole fluids to form a new solution. The resulting mix of corrosive compound and downhole fluids exhibits corrosive properties that are significantly superior to that of the downhole fluids alone. As a result, the dissolution of the dissolvable frac plug 100 after the beach of the internal chamber 120 is accelerated by several hours. Further, the enhanced dissolution facilitates the removal of the dissolved frac plug from the wellbore.
The dissolvable frac plug 100 is sized to perform its various functions, such as isolating zones of the wellbore. Accordingly, an external diameter of the dissolvable plug 100 may be comparable to a diameter of a wellbore, for example. Further, a size of the dissolvable frac plug 100 may be a factor in the plug's dissolution time. For example, a smaller dissolvable frac plug 100 may dissolve faster than a larger plug for the same concentration of corrosive solution. The size of the dissolvable frac plug 100 may also affect the quantity of corrosive compound carried in the internal chamber 120, which in turn affects the dissolution time of the plug 100. In light of these and other relevant factors, an exemplary dissolvable frac plug 100 may weight about 10 lbs., and have a length of about 13.82 inches, with an internal diameter for the mandrel core 101 of about 2 inches, and an external diameter for the plug of about 4.25 inches, in some embodiments. It should be noted that other dimensions for the dissolvable frac plug 100 are possible depending on properties of the plug (e.g., dissolution time, weight, etc.) are balanced or prioritized in its design.
Various combinations of the dissolvable material of the frac plug 100 and the corrosive compound may be used. For example, a dissolvable portion of a frag plug 100 may be composed of a material that is degradable when exposed to a high basicity (or high pH) compound. In some embodiments, the dissolvable frag plug material may be reactive with a high acidity (low pH) compound. In other embodiments, a property of the dissolvable frac plug material and the corrosive compound other than the pH scale may precipitate their reaction and cause the dissolution a portion of the frac plug 100. In embodiments where the dissolvable frac plug 100 or portion of the frac plug 100 is made of a magnesium or aluminum alloy, the corrosive compound may comprise a compound that forms an acidic solution when mixed with downhole fluids. The use of a compound that becomes corrosive only when mixed with downhole fluids alleviates the need to protect the internal chamber 120 from reacting with the compound (for example, with an internal coating), in order to guard against a premature dissolution from inside the internal chamber 120.
In a preferred embodiment, the corrosive compound comprises sodium bisulfate, also known sodium hydrogen bisulfate or sodium acid sulfate (NaHSO4). Sodium bisulfate is an acidic salt often used to create acidic solutions when mixed with one or more solvents such as water. The acidic salt comes in the form of a powder or similar granular structure. However, other suitable compounds have may different structures, such as one or more solid blocks of material that may dissolve upon contact with downhole fluids. The resulting acidic solution degrades the magnesium or aluminum alloys of the dissolvable plug 100 at a faster rate than water alone or any of the low acidity downhole fluids circulating in the wellbore. Various quantities of sodium sulfate may be suitable depending on the size of the frac plug 100, the downhole conditions, and other operational factors. For example, at a site where the downhole fluids have a relative elevated salinity, acidity, and/or temperature, a smaller quantity of sodium bisulfate may be sufficient to enhance the dissolution of the frac plug 100. In some embodiments, the amount of sodium bisulfate to be used is preferably about three times the volume of the dissolvable portion of the frac plug. This ratio may provide an optimum rate and degree of dissolution, in some examples.
Aluminum chloride (AlCl3) may also serve as a corrosive compound for the dissolvable plug 100, in some embodiments. As with sodium bisulfate, aluminum chloride can be packed inside the internal chamber 120 as a solid or granular compound or a powder that can form an acidic solution when mixed with downhole fluids to degrade the dissolvable plug 100. This can be mixed with the sodium bisulfate or provided in a different adjacent chamber. If desired, multiple chambers of each powder or even multiple chambers of different powders can be used. And as wellbores are typically flush with ground water, the release of the powder or powders creates an acidic, corrosive environment that more rapidly dissolves the plug than water alone.
In a preferred embodiment, multiple dissolvable frac plugs such as 100, 200, 300 or 400, for example, from 1 to 85, from 5 to 80, from 10 to 75, from 15 to 70, from 20 to 65, from 25 to 60, from 30 to 55, from 35 to 50, from 40 to 45 dissolvable frac plugs can be provided, each of the dissolvable plugs containing a different kind of tracer or dye compound to be released to water or other wellbore fluids and flow back to land surface, which allows the end user on the surface to identify which frac plug dissolves and where the flow originates from due to different and unique chemical features of the tracer compounds.
It should be understood that combinations of described features or steps are contemplated even if they are not described directly together or not in the same context.
It should be understood that claims that include fewer limitations, broader claims, such as claims without requiring a certain feature or process step in the appended claim or in the specification, clarifications to the claim elements, different combinations, and alternative implementations based on the specification, or different uses, are also contemplated by the embodiments of the present invention.
The term “about” herein specifically includes ±10% from the indicated values in the range.
Other terms or words that are used herein are directed to those of ordinary skill in the art in this field of technology and the meaning of those terms or words will be understood from terminology used in that field or can be reasonably interpreted based on the plain English meaning of the words in conjunction with knowledge in this field of technology. This includes an understanding of implicit features that for example may involve multiple possibilities, but to a person of ordinary skill in the art a reasonable or primary understanding or meaning is understood.
It should be understood that the above-described examples are merely illustrative of some of the many specific examples that represent the principles described herein. Clearly, those skilled in the art can readily devise numerous other arrangements without departing from the scope as defined by the following claims.
This application is a continuation of U.S. application Ser. No.: 16/716,338 filed Dec. 16, 2019, which claims the benefit of priority to U.S. application Ser. No. 62/820,202, filed Mar. 18, 2019, each of which is incorporated herein by reference in its entirety.
| Number | Name | Date | Kind |
|---|---|---|---|
| 10947809 | Subbaraman | Mar 2021 | B2 |
| 20180087369 | Sherman | Mar 2018 | A1 |
| 20180306027 | Sherman | Oct 2018 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 62820202 | Mar 2019 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 16716338 | Dec 2019 | US |
| Child | 17490740 | US |
