The invention relates to a downhole apparatus for performing multiple downhole operations in a well. More particularly, the invention relates to a downhole apparatus for plugging, punching and/or cutting a production tubular in a single run into the well. The downhole apparatus is configured for isolating a section of the well by setting a plug by means of a plug setting tool. The downhole apparatus is further configured for punching holes in the production tubular above the plug to enable circulation of a fluid from an inside of the production tubular to an annulus on an outside of the production tubular, or vice versa. The downhole apparatus is further configured for forming a cut in the production tubular above the plug for retrieval to a surface of the tubular section above the cut. A lower portion of the downhole apparatus comprises the plug and means for setting the plug. An upper portion of the downhole apparatus comprises a tool string. The lower portion and the upper portion of the downhole apparatus is mechanically coupled by a sleeve. The sleeve is configured to house a tubing puncher and/or a tubing cutter. The downhole apparatus is configured to be run into the well by a wireline. The invention also relates to a method for performing downhole operations in a well using the downhole apparatus.
A wireline or slickline is often used to lower a bottom hole assembly from a surface into a wellbore; to supply energy to the bottom hole assembly and to transmit data from the wellbore. Wireline operations may comprise plugging, reservoir measurements such as pressure, temperature and flow, leak detection, pipe cutting and punching. The operations may be performed to optimize production from the well or repair a faulty barrier in the well. The bottom hole assembly may comprise of several tools, for example running and pulling tools, fishing tools, explosive tools and logging tools.
When preparing a well for recompletion or permanent abandonment, there is an operational sequence involving steps of:
Subsequently, the production tubular above the cut will be retrieved from the wellbore. The operational sequence is typically performed in several wireline runs into the wellbore. A first run is performed to install a barrier by means of a barrier plug. The tool string includes the barrier plug itself and necessary tooling to position and install the barrier plug at a correct location. The barrier plug commonly being a retrievable or permanent bridge plug. Then, a second run is performed to punch a hole in the production tubular to enable circulation of a heavy fluid into the production tubular and a surrounding annulus between the production tubular and a casing. The tool string includes a hole punching tool, typically an explosive device or a mechanical device or a device of another working principle. Finally, a third run is performed to cut the production tubular above the barrier plug. The tool string includes a tubing cutting tool, typically a mechanical device or an explosive device or a chemical device or a device of another working principles. In some instances, a fourth run is performed to install a junk basket in the production tubular.
Performing the above-mentioned operational sequence in three separate runs requires a relatively long operational time. It involves three separate exercises of lowering, operating and hoisting the wireline toolstring in and out of the wellbore. There are further two rigging sequences between the runs to change toolstring. The long operational time entails a high rig and equipment rental cost. The cost could be reduced if the number of runs into the well is reduced.
From the prior art, it is known to perform the barrier plug installation and tubing punching in a single run in the well using an integrated tool string consisting of a barrier plug, a plug setting tool and a tubing punching tool, ref. “Mechanical Puncher Tool” by Interwell Norway AS. Patent document EP3085882 discloses a method of plugging a well using cement and cutting the well tubular in a single run. The method presupposes that a barrier plug is in place to isolate the lower part of the well tubular prior to cementing.
It is an objective of the invention to provide an apparatus that is capable of at least reducing one run into the well during barrier installation, punching and cutting operations. It is also an objective of the invention to provide an apparatus that can perform all three operations in a single run into the wellbore. It is a further objective of the invention to provide an apparatus that can perform all three operations and install a junk basket in a single run into the wellbore.
The invention has for its object to remedy or to reduce at least one of the drawbacks of the prior art, or at least provide a useful alternative to prior art.
The object is achieved through features, which are specified in the description below and in the claims that follow.
The invention is defined by the independent patent claims. The dependent claims define advantageous embodiments of the invention.
In a first aspect, the invention relates more particularly a downhole apparatus, the downhole apparatus comprising:
wherein an upper portion of a sleeve is connectable to a lower portion of the tool string, and a lower portion of the sleeve is arranged to receive the plug and the means for setting the plug.
The first end of the sleeve may be an upper end and the second end of the sleeve may be a lower end when the apparatus is positioned in a well. The sleeve may be a hollow cylindrical. Other similar definitions of a sleeve may be a mandrel, a bushing, a casing or a tube.
The plug may for example be a retrievable or permanent bridge plug. The lower portion of the sleeve may be connected to the means for setting the plug, such that when releasing the sleeve from the tool string, the sleeve may stay in place with the plug and the means for setting the plug. The tool string may be displaced upwards within the production tubing by pulling after releasing the sleeve. The tool string may comprise auxiliary devices for operating the downhole apparatus, e.g. sensors, control devices, hydraulic actuators, electric motors etc. The upper portion of the sleeve may be connected to the lower portion of the tool string by means of a releasable connection, such as shear pins or screw mechanism.
In one embodiment, the sleeve, between its upper and lower portion, may be configured to house at least one tool. In one embodiment, the sleeve may house one tool. In another embodiment, the sleeve may house more than one tool. The at least one tool may be configured to perform downhole operations in the well. The at least one tool may be operated electrically or hydraulically. Electric current may for example be supplied via a wireline from surface, or from batteries in the tool string. Hydraulic power may be supplied from an actuator in the tool string.
In one embodiment, the sleeve, between its upper and lower portion, may be configured to house a first tool and a second tool. The first tool may be a tubing punching tool. The second tool may be a tubing cutting tool. The first tool and the second tool may be arranged in series along a longitudinal axis of the tool string. In one embodiment, the two tools may be connected to each other. In one embodiment, the first tool may be arranged closest to the tool string, and may be connected to the tool string. The two tools may be operated independently of each other. Means for controlling the second tool may be arranged from the tool string and through the first tool.
The sleeve may house at least a portion of the means for setting the plug. The means for setting the plug may be a plug setting tool. In one embodiment, the means for setting the plug may be an integral part of the plug. In one embodiment, the sleeve may house the entire means for setting the plug. The plug may be connected to the sleeve. The sleeve and plug may form an integral unit.
In one embodiment, the means for setting the plug may communicate with a control device via a communication means. The communication means may be a communication line, an activation line or wireless communication. At least a portion of the communication line or activation line may be integrated in a body of the sleeve. The control device may be arranged in the tool string. The communication line or activation line may for example be an electric line or a hydraulic line. In one embodiment, the portion of the communication line or activation line being integrated in the body of the sleeve may communicate with the not integrated part of the communication line or activation line via wireless means such as inductive couplers or pressure pulses. In one embodiment, the communication line or activation line may be free-running from the tool string to the plug setting tool. Free-running meaning not integrated in a body of the sleeve.
In one embodiment, the upper portion of the sleeve may be connectable to the tool string by a releasable latching mechanism. The latching mechanism may interact with an internal surface of the sleeve. The latching mechanism may have latching dogs. The latching dogs may be complementary to grooves in the sleeve. The latching mechanism may be operable between an engaged and an open position. In the open position, the tool string may move freely relative to the sleeve. In the engaged position, the sleeve and the tool string may be locked from moving relative to each other in an axial direction. The latching mechanism may be activated by an operator command, or automatically, for example by some predetermined hydraulic pressure value. In one embodiment, the sleeve may be connectable to the tool string by means of ball grabs.
In one embodiment, the sleeve may be configured as a junk basket when disconnected from the tool string. The junk basket may collect debris, such as; rust, metal swarf, scale, sand, silt etc. The debris may be retrieved together with the sleeve. In one embodiment, the sleeve may be releasable from the plug for retrieval of the sleeve to surface.
In one embodiment, the tool string may comprise a multifinger caliper. The multifinger caliper comprises a plurality of radially extendable rods, the rods also being defined as fingers. When extended, the fingers will measure changes in the internal diameter of a tubular when the multifinger caliper is moved up the tubular. By measuring the internal diameter of the tubular, the multifinger caliper may detect changes in the surface condition, e.g. corrosion or depositions. The multifinger caliper may be arranged on the tool string above the sleeve. Performing measurements using a multifinger caliper would normally require an additional run in the well if using traditional tools. Including a multifinger caliper on the tool string may enable another operation to be performed in the same run as the previously mentioned operations.
In one embodiment, the tool string may comprise a wireline tractor. The wireline tractor can move along the well for displacing the tool string and downhole apparatus. This may be a preferable embodiment in deviated or horizontal wells, where gravity alone is not sufficient to displace the downhole apparatus and tool string. In one embodiment, the wireline tractor may comprise grinding elements. The wireline tractor may further comprise wheels, wherein the grinding elements may be arranged on the wheels. The grinding elements may be configured to perform tubing punching. In one embodiment, the grinding elements may replace the tubing puncher for punching the tubular in the well.
In a second aspect, the invention relates more particularly to a method for a downhole operation using the downhole apparatus according to any of the preceding claims, wherein the method comprises the steps of:
In one embodiment, the method, after step b), may further comprise the steps of:
The well tubular may be perforated by operating the tubing puncher. In one embodiment, the well tubular may be perforated by operating the grinding elements on the wireline tractor.
In one embodiment of the method, after step b), further comprises the steps of:
The well tubular may be cut by operating a tubing cutter.
In one embodiment, the method, after step b), further comprises the steps of:
In the following is described an example of a preferred embodiment illustrated in the accompanying drawings, wherein:
The figures are depicted in a simplified manner, and details that are not relevant to illustrate what is new with the invention may have been excluded from the figures. The different elements in the figures may necessarily not be shown in the correct scale in relation to each other. Equal reference numbers refer to equal or similar elements. In what follows, the reference numeral 1 indicates a downhole apparatus according to the invention.
The downhole apparatus 1 comprises a sleeve 2. An upper portion 210 of the sleeve 2 is releasably connected to a lower portion 310 of a tool string 3 by means of a latching mechanism 32. A lower portion 211 of the sleeve 2 is connected to a plug 4 and a plug setting tool 41. The sleeve 2 is shown housing a tubing punching tool 5 and a tubing cutting tool 6.
A tubing cutting tool 6, in the following called cutter, is connected to the puncher 5. The cutter 6 is configured to cut the production tubular 510 at a desired location above the sleeve 2. After cutting, the tubular 510 above the cut 530 may be retrieved to surface. The cutter 6 may be a mechanical device or an explosive device or a chemical device or a device of another working principle. To avoid risk of the cutter 6 getting stuck due to tubing displacement, for example scissoring, after cutting, it is an advantage to have the cutter 6 at the lower end of the tool string 3, however, this is not a requirement.
In use, the downhole apparatus 1 will be lowered into the well 500. The plug 4 is set to isolate a section of the well 500 above the plug 4, see
At an elevation above the sleeve 2, the puncher 5 can be operated to punch one or more holes 520 in the well tubular 510, see
It should be noted that the above-mentioned embodiment illustrates rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements.
The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
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20171843 | Nov 2017 | NO | national |
This current application is a continuation application of U.S. patent application Ser. No. 16/761,874 filed May 6, 2020 which claims priority to PCT Application NO2018/050279 filed Nov. 15, 2018 which claims priority to Norwegian Patent Application No. 20171843 filed Nov. 20, 2017, each of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 16761874 | May 2020 | US |
Child | 17941766 | US |