This application claims priority from Application 1913635.7 filed on Sep. 20, 2019 in the United Kingdom.
The present disclosure relates to a downhole packer apparatus, system and method for establishing a seal in an annulus, such as within a wellbore.
Downhole sealing devices known as packers are used extensively in the oil and gas industry for sealing an annulus in a wellbore. In some instances, the packer takes the form of a casing packer, whereby the annulus to be sealed is between the packer and associated bore-lining tubing, e.g. casing or liner, and a bore wall. In other instances, the packer takes the form of a production packer, whereby the annulus to be sealed is between the packer and associated production tubing and the bore-lining tubing.
Conventional packers comprise an elastomeric annular sealing element mounted on a mandrel, the sealing element being expandable outwardly in the radial direction to engage the bore wall or the bore-lining tubing in which the packer is located, and thus sealing the annulus defined between the packer and the bore wall or bore-lining tubing.
Once in place and sealing the annulus, the packer may be utilised to isolate a region from fluid flow. The pressure on the fluid side of the packer may increase as operations are carried out in the isolated region. In some cases, if the pressure acting on the sealing element is too great, the sealing element of the packer may experience extrusion, lack of seal or compression set. In such an instance, the packer is not effective.
An aspect of the present disclosure relates to a downhole packer apparatus for use in establishing a seal in an annulus between the apparatus and a wall of a bore or bore-lining tubing. The apparatus includes each of a body, a plurality of sealing elements configured for mounting on the body, each sealing element configured to engage the wall of the bore or bore-lining tubing so as to divide the annulus into a plurality of annulus portions.
A bypass arrangement is operatively associated with each of the sealing elements, each bypass arrangement having a fluid communication arrangement for communicating fluid between the respective plurality of annulus portions, and a valve arrangement configured to control fluid flow between the respective plurality of the annulus portions via the fluid communication arrangement. The valve arrangement is configurable between a first configuration in which fluid communication between the respective plurality of annulus portions is prevented and a second configuration in which fluid communication between the respective plurality of annulus portions is permitted, in response to a predetermined threshold pressure differential across the valve arrangement.
In use, the apparatus may be positioned downhole so as to form an annulus between the apparatus and a wall of a bore or bore-lining tubing and actuated to establish a seal. Each seal element is configured to engage the wall of the bore or the bore-lining tubing to divide the annulus into a plurality of annulus portions. Each valve arrangement is configurable in a first configuration preventing fluid communication between the respective plurality of annulus portions and is reconfigurable to a second configuration permitting fluid communication between the respective plurality of annulus portions. The valve arrangement is reconfigurable between the first and second configurations in response to a predetermined pressure differential across the valve arrangement.
The bypass arrangements may be sequentially operable. In particular, the valve arrangements may be sequentially reconfigurable from their first configuration to their second configuration to permit fluid communication between the respective plurality of annulus portions. Thus, in sequential operation of the bypass arrangements, fluid may be communicated between the annulus portions sequentially to step down the pressure in each annulus portion in sequence.
Beneficially, the ability to step down the pressure in each annulus portion in sequence results in an apparatus that can withstand a substantially greater pressure differential than conventional packers, and thus provides effective isolation in high pressure downhole environments, without decreasing the effective sealing capability of the sealing elements.
As described above, each sealing element is configured to engage the wall of the bore or bore-lining tubing so as to divide the annulus into a plurality of annulus portions.
The apparatus may be configured so that when the sealing elements engage the wall of the bore or bore-lining tubing, the pressure differential across each valve arrangement corresponds to the pressure differential across the respective sealing element. The predetermined threshold pressure differential may be determined according to the pressure differential that each sealing element is able to withstand without a decrease in the effective sealing capability of the sealing element.
As described above, each valve arrangement is reconfigurable between the first and second configurations in response to a predetermined pressure differential across said valve arrangement. The predetermined threshold pressure differential may be a pressure drop (i.e. decrease in pressure from an upstream side of the valve arrangement to a downstream side of the valve arrangement).
The predetermined threshold pressure differential may be an integer pressure drop across said valve arrangement. Alternatively, the predetermined threshold pressure differential may be a percentage pressure drop.
Each valve arrangement may be a one-directional valve arrangement. Each valve arrangement may include or take the form of a check valve or the like.
Each valve arrangement may be reconfigurable from the first configuration to the second configuration when the pressure differential across the valve arrangement is equal to or greater than the predetermined threshold. Each valve arrangement may be reconfigurable from the second configuration to the first configuration when the pressure differential across the valve arrangement drops below the predetermined threshold.
Alternatively, each valve arrangement may be reconfigurable from the first configuration to the second configuration when the pressure differential across the valve arrangement is greater than the predetermined threshold. Each valve arrangement may be reconfigurable from the second configuration to the first configuration when the pressure differential across the valve arrangement is equal to or less than the predetermined threshold.
Each valve arrangement may comprise a piston. Each piston may have a sealing position wherein the respective valve arrangement is in the first configuration. Each piston may have a filling position wherein the respective valve arrangement is in the second configuration.
Each valve arrangement may comprise one or more biasing element. The biasing element may be a spring. Each biasing element may bias the respective piston towards its sealing position. Each piston may be movable from the sealing position to the filling position, against the bias of the respective biasing element, to reconfigure the respective valve arrangement from the first configuration to the second configuration, in response to the predetermined pressure differential.
The apparatus may include a valve sleeve associated with each annulus portion. Each valve sleeve may be mounted on the body. Each valve arrangement may be configured to control fluid flow from a first annulus portion of the respective plurality of annulus portions to a second annulus portion of the respective plurality of annulus portions via the respective fluid communication arrangement. Each valve arrangement may be configured to control fluid flow from a first annulus portion of the respective plurality of annulus portions to the respective fluid communication arrangement. Each valve arrangement may be mounted in the valve sleeve associated with the first annulus portion of the respective plurality of annulus portions.
The fluid communication arrangement may be configured to communicate liquid and/or gas.
The fluid communication arrangement may include a sealed space. As described above, the apparatus may also include a valve sleeve associated with each annulus portion. The sealed space may be provided between the valve sleeve associated with the first annulus portion of the respective plurality of annulus portions and the body. Each sealed space may be sealed by seals, for example a pair of seals. The seals may be axially spaced. The sealed space may be annular. Flow of fluid from the first annulus portion of the respective plurality of annulus portions to the respective sealed space may be controlled by the respective valve arrangement.
The fluid communication arrangement may include a conduit. Each conduit may be a channel, a pipe, a line or the like, suitable for receiving and communicating fluid. A first end of the conduit may be configured for fluid communication with the respective sealed space. A second end of the conduit may be configured for fluid communication with the second annulus portion of the respective plurality of annulus portions. The conduit may be circumferentially spaced from the valve arrangement. The conduit may extend through the body. The conduit may extend through the valve sleeve associated with the second annulus portion of the respective plurality of annulus portions. Each conduit may extend the length of the body. Each conduit may be blocked, closed, covered or sealed at each end of the body.
The conduits may be circumferentially distributed. The fluid conduits may be circumferentially spaced 15 degrees apart.
The conduits may be circumferentially distributed. The fluid conduits may be circumferentially spaced 15 degrees apart.
Each bypass arrangement may be configured to prevent a pressure differential across the respective sealing element of the plurality of sealing elements exceeding the predetermined threshold pressure differential.
As described above, the bypass arrangements may be configured for sequential operation.
A first of the bypass arrangements may be configured for fluid communication with a first end of the apparatus. The first of the bypass arrangements may be a first bypass arrangement in the sequence of operation of the bypass arrangements. The first of the bypass arrangements may be configured for initiating sequential operation of the bypass arrangements in response to receiving fluid from the first end of the apparatus.
Each bypass arrangement may be configured to control fluid flow between the respective plurality of annulus portions in a first direction. The first direction may be from uphole to downhole. Alternatively, the first direction may be from downhole to uphole.
The bypass arrangement may define a forward bypass arrangement and the apparatus may further comprise a reverse bypass arrangement operatively associated with each of the sealing elements. Each reverse bypass arrangement may be configured to control fluid flow between the respective plurality of annulus portions in a second direction opposite the first direction.
The reverse bypass arrangements may be configured for sequential operation. The reverse bypass arrangements may be configured for operation in a sequence of operation opposite to the sequence of operation of the forward bypass arrangements. In use, the reverse bypass arrangements may allow for reverse operation of the apparatus. Accordingly, the apparatus may be utilised to effectively isolate the annulus on either side of the apparatus without removal and refitting of the apparatus.
A first of the reverse bypass arrangements may be configured for fluid communication with a second end of the apparatus. The second end of the apparatus may be an end of the apparatus opposite the first end of the apparatus. The first of the reverse bypass arrangements may be a first reverse bypass arrangement in the reverse sequence of operation of the reverse bypass arrangements. The first of the reverse bypass arrangements may be configured for initiating the sequential operation of the reverse bypass arrangements in response to receiving fluid from the second end of the apparatus.
As described above, the apparatus comprises a body and a plurality of sealing elements configured for mounting on the body.
The plurality of sealing elements may comprise four sealing elements. However, it will be understood that the apparatus may alternatively comprise any suitable number of sealing elements e.g 2, 3, 5, 6, . . . n sealing elements.
Each sealing element of the plurality of sealing elements may be actuable between a run in configuration and a sealing configuration. Each sealing element may engage the wall of the bore or bore-lining tubing so as to divide the annulus into a plurality of annulus portions when the sealing element is in its sealing configuration.
Each sealing element may be elastomeric.
The body may be a mandrel, a tubular, a pipe, a tubing, a sleeve or the like. The body may include connectors at each end of the body for connection to a tubular, a pipe, a string or the like. The connectors may include threaded connectors, such as threaded pin and/or box connectors.
The body may be a unitary body. Alternatively, the body may include a plurality of body portions. The body portions may be axially spaced apart. Each respective sealing element and valve sleeve may be mounted on a respective body portion.
Another aspect of the present disclosure relates to a downhole system includes the downhole packer apparatus as described above.
Another aspect of the present disclosure relates to use of the downhole packer apparatus described above to seal an annulus in a wellbore.
Another aspect of the present disclosure relates to a downhole packer apparatus. The apparatus may be configured to establish a seal in an annulus between the apparatus and a wall of a bore or bore-lining tubing. The apparatus may include a body. The apparatus may include a plurality of sealing elements. The plurality of sealing elements may be configured for mounting on the body. Each sealing element may be configured to engage the wall of a bore or bore-lining tubing so as to divide the annulus into a plurality of annulus portions. The apparatus may include a bypass arrangement operatively associated with each of the sealing elements. The bypass arrangement may comprise a fluid communication arrangement for communicating fluid between the respective plurality of annulus portions. The bypass arrangement may include a valve arrangement configured to control fluid flow between the respective plurality of annulus portions via the fluid communication arrangement. The valve arrangement may be configurable between a first configuration in which fluid communication between the respective plurality of annulus portions is prevented and a second configuration in which fluid communication between the respective plurality of annulus portions is permitted. The valve arrangement may be configurable between the first and second configurations in response to a predetermined threshold pressure differential across the valve arrangement.
It should be understood that the features defined above in accordance with any aspect of the disclosure or below in relation to any specific example, may be utilised, either alone or in combination, with any other defined feature, in any other aspect or example.
These and other aspects of the present disclosure will now be described, by way of example only, with reference to the accompanying drawings, in which:
In reference to
The apparatus 10 includes a plurality of conduit systems (only an initiation conduit system 24 can be seen in
The apparatus 10 comprises a plurality of valve arrangements 26 (only the first valve arrangement 26a can be seen in
The valve arrangements 28 are configured such that the pressure differential across each sealing element 14 will not exceed a predetermined extent to which the sealing element 14 will function effectively. Four sealing elements 14 are provided in the present example.
In reference to
The first valve arrangement 26a is mounted in the first valve sleeve 30a. The first valve arrangement 26a comprises a piston 32 and a biasing element 34. In the present example the biasing element 34 is a spring. The piston 32 is moveable between a sealing position and a filling position, as will be described below with reference to the operation of the first valve arrangement 26a. A piston seal 36 is mounted on the piston 32. In the present example the piston seal 36 is an o-ring. The piston seal 36 provides isolation between ends of the piston 32. The position of the piston seal 36 controls flow across the first valve arrangement 26a. The first valve sleeve 30a comprises an annulus side port 38 that extends between the first valve arrangement 26a and the first annulus portion 18a. The annulus side port 38 is in communication with the first annulus 18a at an outer surface of the first valve sleeve 30a adjacent the casing 16. The first cavity seal pair 42a seal the first space 44a from the first annulus portion 18a. The first valve sleeve 30a further comprises a pair of space side ports 40 that extend between the first valve arrangement 26a and the first space 44a. The space side ports 40 are in communication with the first space 44a at an internal surface of the valve sleeve 30a adjacent the body 12. As is described in greater detail below, the first space 44a is in fluid communication with a second annulus portion 18b via a first conduit system 46 (not shown in
The first valve arrangement 26a is mounted in the first valve sleeve 30a. The first valve arrangement 26a comprises a piston 32 and a biasing element 34. In the present example the biasing element 34 is a spring. The piston 32 is moveable between a sealing position and a filling position, as will be described below with reference to the operation of the first valve arrangement 26a. A piston seal 36 is mounted on the piston 32. In the present example the piston seal 36 is an o-ring. The piston seal 36 provides isolation between ends of the piston 32. The position of the piston seal 36 controls flow across the first valve arrangement 26a. The first valve sleeve 30a comprises an annulus side port 38 that extends between the first valve arrangement 26a and the first annulus portion 18a. The annulus side port 38 is in communication with the first annulus 18a at an outer surface of the first valve sleeve 30a adjacent the casing 16. The first cavity seal pair 42a seal the first space 44a from the first annulus portion 18a. The first valve sleeve 30a further comprises a pair of space side ports 40 that extend between the first valve arrangement 26a and the first space 44a. The space side ports 40 are in communication with the first space 44a at an internal surface of the valve sleeve 30a adjacent the body 12. As is described in greater detail below, the first space 44a is in fluid communication with a second annulus portion 18b via a first conduit system 46 (not shown in
In reference to
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Reverse operation of the apparatus 10 will be described with reference to
It will be understood that various modifications may be made without departing from the scope of the claimed invention.
For example, wherein in the illustrated apparatus described above the body is in the form of a mandrel, the body may alternatively be in the form of a tubular, a pipe, a tubing, a sleeve or the like.
In the illustrated apparatus described above the annulus is formed between the apparatus and a casing, however the annulus may alternatively be between the apparatus and a bore-wall.
In the illustrated apparatus described above the cavity seal pairs are o-rings axially spaced apart on the body. The cavity seal pairs may alternatively be provided on the valve sleeves, or on the valve sleeves and the body. Each cavity seal may alternatively be any other suitable seal type to form a sealed space therebetween.
In the illustrated apparatus described above the valve arrangements comprise check valves, however the valve arrangements may alternatively comprise any other suitable valve type.
In the illustrated apparatus described above there are four sealing elements, however there may alternatively be any number of sealing elements necessary such that the apparatus can provide isolation of an end of the apparatus whilst ensuring that the sealing element at the isolated end of the apparatus has a pressure differential across it that does not exceed the predetermined threshold. There is a bypass arrangement associated with each sealing element. Any number of sealing elements and bypass arrangements may be provided to ensure that the pressure is sufficiently reduced in the subsequent annulus portions that one of the valve arrangements will not permit fluid flow.
In the illustrated apparatus described above the valve arrangement biasing element is a spring, however the biasing element may alternatively be any other suitable device.
In the illustrated apparatus described above the valve arrangement piston seal is an o-ring, however any suitable seal type may be used.
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