The present invention relates to an improved sealing apparatus, and particularly to a sealing apparatus suitable for sealing a well annulus from both uphole and downhole pressure.
Sealing devices are used in well bores to seal the annulus between the well casing and a tubular, such as a production tube passing through the well bore. Conventional devices, such as packers, come in a number of types. Two of the most widely used types are inflatable packers and compressed element packers. In these packers, the seal is created by the application of pressure through the sealing element. One of the drawbacks of these types of packers is that enough pressure has to be applied during the setting of the packer to make a seal strong enough to withstand all the forces that will be applied to the seal during use
A cup seal packer, of the type described in the applicant's co-pending European Patent Application EP1503031 overcomes some of the drawbacks of conventional packers by providing a cup seal which requires only sufficient load be applied to form an initial contact seal with the well casing. The cup seal packer is self-energising by using well pressure to make the seal with the well casing. One of the drawbacks of a cup seal packer of this type, however, is they can only safely hold pressure from one direction. To overcome this drawback, if it is required to provide sealing from above and below two cup seals are used, the cups facing in opposite directions.
According to a first aspect of the present invention there is provided a sealing apparatus for sealing an annulus, the apparatus comprising:
a first sealing element adapted for sealing the annulus against fluid pressure from above the sealing apparatus and adapted to be actuated by fluid pressure from above the apparatus; and
a second sealing element adapted for sealing the annulus against fluid pressure from below the sealing apparatus and adapted to be actuated by fluid pressure from below the apparatus;
wherein the sealing elements are arranged such that the second sealing element is, in use, above the first sealing element.
It will be understood that the terms “above” and “below” are used to explain the relative positions of the sealing elements in a substantially vertical borehole. The invention can equally be used in inclined or horizontal wells in which case the second sealing element will be located uphole from the first sealing element.
In one embodiment, this arrangement provides a sealing apparatus which can seal from pressure applied from above, in which case the upper sealing element is substantially redundant and the lower sealing element is active, or from below, in which case the lower sealing element is substantially redundant and the upper sealing element is active. Arranging the sealing elements in this way, that is with the redundant sealing element located on the high pressure side of the active sealing element, is advantageous primarily because the force exerted on the sealing apparatus is only transmitted through one of the sealing elements as the redundant sealing element can be bypassed. This contrasts with the prior art, in which the active seal element is located before the redundant element, and the load applied to the active element has to be transmitted through the redundant element. In the prior art, heavy duty metal collars have to be provided to transmit this force. As the present sealing apparatus, in one embodiment, no longer requires the collars, more space is available either to increase the size of the apparatus throughbore or to increase the thickness of the sealing elements.
Preferably, the sealing elements are deformable.
Preferably, the sealing elements are cup-shaped.
Preferably, in use and when a pressure differential exists across the sealing apparatus, there is an active sealing element and a substantially redundant sealing element. By this it is meant the majority of the seal provided by the sealing apparatus is provided by one of the sealing elements, that is the active sealing element.
Preferably, the sealing elements are adapted to be mounted on a mandrel so as to define a volume between each sealing element and the mandrel
Preferably, each sealing element comprises a base portion and a tip portion.
Preferably, the first and second sealing element tip portions are arranged facing one another.
Preferably, the first sealing element tip portion is engaged with a first side of a ring member.
Preferably, the second sealing element tip portion is engaged with a second side of the ring member.
Most preferably, the first and second sealing elements are sealed to the ring member.
Preferably, the first and second sealing elements are pinned to the ring member.
Alternatively, or additionally, the first and second sealing elements are adhered or clamped to the ring member.
Alternatively or additionally, the first and second sealing elements are attached to the ring member by any appropriate fixing means.
Preferably, the ring member defines an “H” section.
Preferably, the first sealing element base portion is attached to a first tubular.
Preferably, the second sealing element base portion is attached to a second tubular.
Preferably, when located in a conduit, the sealing apparatus defines the annulus with a conduit wall.
The conduit wall may be a cased bore, a lined bore or an open hole.
Preferably, the sealing apparatus is adapted to form an initial seal with a conduit wall through application of a setting force to the sealing elements.
Preferably, the setting force is a compression force.
The sealing apparatus may form an initial seal by buckling.
Preferably, an external surface of each sealing element defines an initial engagement portion adapted to sealingly engage a conduit wall upon application of the setting force.
Preferably, the initial engagement portion is a circumferential band around each sealing element.
Preferably, the initial engagement portion is between the tip portion and the base portion of each sealing element.
Most preferably, the initial engagement portion is spaced from the tip portion and the base portion of each sealing element.
Preferably, each sealing element defines a passage extending through the sealing element from the sealing element external surface to a sealing element internal surface. Provision of a passage permits fluid to pass through the sealing element.
Preferably, the end of the passage defined by the sealing element external surface is at least partially located between the tip portion and the initial engagement portion.
Alternatively, the end of the passage defined by the sealing element external surface is wholly located within the initial engagement portion.
In one embodiment, where the sealing apparatus is sealing against a high pressure fluid, the opening of the active sealing element passage is at least partially located on the high pressure side of the initial engagement portion. This arrangement permits fluid from the high pressure side of the active sealing element to enter the volume between the sealing elements and the mandrel. The pressurised fluid then presses on the internal surface of the active sealing element forcing the active sealing element into a tighter engagement with the conduit wall, improving the sealing effect of the sealing apparatus, that is, a further sealing effect is provided by hydraulic expansion. In the same embodiment, the high pressure fluid displaces the redundant sealing element sufficiently from the conduit wall to expose the opening of the redundant sealing element passage providing a further, or alternative, fluid path for the high pressure fluid into the volume between the sealing elements and the mandrel.
Preferably, there are a plurality of passages in each sealing element.
Preferably, the ring member defines a communication bore between the annulus and the volume to permit fluid in the annulus actuate at least one of the sealing elements.
Preferably, the ring member defines a plurality of communication bores. Preferably, the communication bore defines a sand screen.
Preferably, the ring member is adapted to move with respect to the mandrel. This movement permits the initial set applied by the setting force to be transmitted from one end of the sealing apparatus through the ring member.
Alternatively, the ring member is fixed with respect to the mandrel. This arrangement permits the compression force to be applied to the sealing apparatus from both ends.
Preferably, the first and second sealing elements are resilient.
Most preferably, the sealing elements are elastomeric.
Preferably each sealing element comprises a relatively hard portion. This hard portion is preferably located towards the sealing element base portion. The presence of a relatively hard portion acts as an anti-extrusion device to prevent the flow of softer material which may otherwise occur when the sealing element is under pressure or exposed to high temperatures, which would compromise the seal.
The hard portion may be rubber, nitrile butadiene rubber, hydrogenated nitrile butadiene rubber, fluoroelastomer, perfluoroelastomer, or tetrafluoroethylene/propylene copolymers or the like.
Preferably, the sealing element and the hard portion share an interface.
Preferably, the sealing element and the hard portion are bonded together at the interface.
Preferably, the bond extends along only part of the interface.
Each sealing element may in addition, or instead, comprise an annular spring member embedded within the sealing element. The spring may be a garter spring or the like. The spring may comprise a relatively hard core within the spring; this also serves as an anti-extrusion device. In certain embodiments, the spring may be a dual spring; that is, a spring embedded within an outer spring. The spring itself has the additional function of improving resilience of the sealing element and assisting its return to the non-expanded state.
The spring may be a single spring or multiple springs.
Each sealing element may in addition, or instead, comprise a seal back up in the form of a metallic band around the circumference of the sealing element.
Preferably, the metal band defines a plurality of fingers or petals which spread as the sealing element expands.
Preferably, there are two metal bands defining fingers or petals, the bands arranged such that when the sealing element is expanded the petals of one band cover the gaps between the petals in the other band. Seal back ups of this type are especially useful when the elastomeric sealing element is made from a soft elastomer. Soft materials extrude more easily then harder materials and a petal seal back up helps prevent extrusion. Seal back ups of this type can also be used where the sealing apparatus has to expand over a larger distance to make a seal with a conduit wall, for example when sealing in open hole.
Alternatively, each sealing element may comprise a plurality of individual petals.
Where the petals are used with a relatively hard material, the petals may be bonded to the hard material.
Preferably, each sealing element is of tapered form.
Preferably, each element is axially tapered.
Preferably, each element is axially tapered towards the element tip portion.
Preferably, the external surface of each sealing element is generally flat, while the internal surface is generally tapered away from the mandrel. A flat outer surface allows for a greater area of contact between the sealing element and the conduit wall.
Preferably, a deformation device is provided to apply a force to an internal surface of the sealing elements to provide an initial deformation of the sealing elements towards, in use, a conduit wall.
Preferably, the force is a radial force.
In one embodiment the deformation device is radially fixed.
In an alternative embodiment the deformation device is radially movable between a run-in position and a radially expanded position.
Preferably, the deformation device is a profiled portion.
Preferably, the profiled portion is defined by the ring member.
Alternatively, the deformation device is a radially deformable sleeve.
According to a second aspect of the present invention there is provided a sealing apparatus for sealing a conduit, the sealing apparatus comprising:
a deformable sealing element adapted for selectively sealing the conduit against pressure from a first side, the sealing element being adapted to be mounted on a mandrel so as to define a volume between the sealing element and the mandrel;
wherein the sealing element defines a passage extending between the volume and an exterior portion of the tool, the passage adapted to permit fluid from a second side of the element to enter the volume.
A sealing apparatus according to an embodiment of the invention permits fluid in the conduit, applying pressure on the side of the sealing element opposite the side which it is desired to provide a seal to move past the sealing element. This ensures the sealing element does not rupture if, for example, the pressure rises in a body of fluid trapped between a pair of sealing apparatus arranged to seal from opposite directions. The trapped fluid can simply move past one or both of the sealing elements.
Preferably, the/each passage is adapted to permit fluid from the first side of the packing tool to enter the volume and cause further deformation of the sealing element.
According to a third aspect of the present invention there is provided a sealing apparatus for sealing an annulus, the sealing apparatus comprising:
a first sealing element for, in use, sealing the annulus against pressure from above the sealing apparatus; and
a second sealing element for, in use, sealing the annulus against pressure from below the sealing apparatus;
wherein the sealing elements are arranged such that the second sealing element is, in use, above the first sealing element.
According to a fourth aspect of the present invention there is provided a sealing apparatus for sealing a conduit, the sealing apparatus comprising:
a deformable sealing element adapted for selectively sealing the conduit, and
a seal back up for preventing extrusion under pressure of the sealing element, the seal back up comprising a sleeve of relatively hard material, the sleeve extending partially along an outer surface of the sealing element, and at least one support band mounted to an external surface of the sleeve.
Provision of a seal back up incorporating a relatively hard material and at least one support band permits the use of the apparatus in higher temperature environments because the seal back up will prevent extrusion of the sealing element. The arrangement also allows for the use of a soft elastomer to be used for the sealing element, allowing for greater expansion.
Preferably, there are a pair of overlapping support bands, each band defining a plurality of petals.
Preferably, the/each band is metal.
It will be understood that the features of one aspect may be equally applicable to the other aspects and have not been repeated for brevity.
Referring firstly to
The sealing apparatus 10 comprises a first elastomeric seal element 20 for sealing the annulus 12 against fluid pressure from above the sealing apparatus 10, and adapted to be actuated by fluid pressure from above the apparatus 10. The sealing apparatus 10 further comprises a second elastomeric sealing element 40 adapted for sealing the annulus 12 against fluid pressure from below the sealing apparatus 10 and adapted to be actuated by fluid pressure from below the apparatus 10. As can be seen from
The first sealing element 20 comprises a tip portion 22 and a base portion 24. The tip portion 22 is attached to a ring member 60 which will be described in due course. The base portion 24 is attached to a first seal element collar 26 which includes a threaded portion 28, most clearly seen in
Referring back to
As can be seen from
The first and second seal elements 20,40 also comprise seal back-ups 30,50 which will be described with reference to
As can be seen from
As can be seen from
The second sealing element 40 also includes a plurality of passages 56 extending from the external surface 58 of the second seal element 40 to the volume 62. The purpose of the passages 36,56 will be discussed in due course.
The ring member 60 describes an H section, and defines a first and a second recess 66,68 which receive the first element tip portion 22 and the second element tip portion 42 respectively. The first and second tip portions 22,42 are secured to the ring member 60 by a series of spiral pins 70 which run around the circumference of the ring member 60.
The ring member 60 also defines a plurality of communication bores 72 providing communication between the annulus 12 and the internal volume 62.
The setting and sealing capabilities of the sealing apparatus 10 will now be described with reference to
As can be seen from
A first seal element initial engagement band 74 engages the conduit wall as does a second sealing element initial engagement band 76. As can be seen in both cases, the seal element passages 36,56 straddle the edge of the initial engagement bands 74,76 such that the first element passage 36 has a portion 78 which lies within the initial engagement band 74 and a further portion 80 which lies between the initial engagement band 74 and the element tip 22. Similarly each second element passage 56 has a portion 82 which lies within the initial engagement band 76 and a portion 84 which lies between the initial engagement band 76 and the element tip 42.
Referring now to
As can be seen from
If the pressure in the annulus section B is sufficiently high pressurised fluid may seep down the annulus 12 passed the initial engagement band 76 of the second seal element 40 and into an annulus portion C defined between the conduit wall 16 and the ring member 60. Pressurised fluid can then flow through the communication bores 72 into the interior volume 62. Alternatively pressurised fluid which has flowed into the interior volume 62 through the second element passages 56 can flow through out of the communication bore 72 into the annulus section C until the pressure is equalised.
If the pressure in the annulus B is removed, the sealing apparatus will return to the configuration shown in
Reference is now made to
The sealing apparatus 110 comprises a first sealing element 120 and a second sealing element 140. The first sealing element 120 comprises a tip portion 122 and a base portion 124. Similarly the second sealing element 140 also comprises a tip portion 142 and a base portion 144. It will be noted in this embodiment, the tip portions 122,142 are at opposite ends of the sealing apparatus 110 rather than adjacent as they were in the sealing apparatus 10 of the first embodiment.
The base portions 124,144 are adhered to a central collar 180, and the tip portions 122,142 are adhered to first and second ring members 160a,160b respectively by an adhesive layer 181a,181b respectively.
The first and second sealing elements each define a plurality of passages 136,156 respectively, the purpose of which will now be described.
Referring to
With the sealing element 120,140 in the partially set configuration, a volume of fluid is trapped in a section “X” of the annulus 112.
Referring now to
By this action, however, the volume of annulus section X is decreased, increasing the pressure on the fluid trapped in the annulus section X. The provision of the second element passages 156, however, means that if the pressure of the trapped fluid increases sufficiently, the fluid can move the second sealing element 140 away from the conduit wall 116 and the trapped fluid pressure can be relieved by fluid escaping through the sealing element passages 156 and into a volume 162b. The volume 162b is pressure balanced with a low pressure section “Z” of the annulus by a ring member communicating bore 174b. Provision of the passages 156 therefore prevents the pressure in annulus section X increasing sufficiently to damage the sealing apparatus 110, and particularly the second sealing element 140.
Reference is now made to
The sealing apparatus 210 comprises a first sealing element 220, a second sealing element 240 and a ring member 260. Each sealing element 220,240 comprises a tip portion 222,242 and a base portion 224, 244.
The first and second sealing elements 220,240 also comprise seal back ups 230,250. The seal back ups 230,250 both comprise a sleeve of hard rubber 284, an inner support layer 286 and an outer support layer 288. The inner and outer support layers 286,288 are in the form of a band of metal petals, the layers 286,288 being arranged to permit the sealing elements 220,240 to expand radially outwards. As the sealing elements 220,240 expand, the petals open up and the layers 286,288 overlap such that gaps between petals of the inner layer 286 are covered by the petals of the outer layer 288 and vice versa.
The provision of back up systems 230, 250 with inner and outer support layers of metal petals 286,288 means a weaker elastomer can be used for the sealing elements 220,240 which permits greater expansion of the sealing elements 220,240 to bridge larger annuluses, which might be encountered, for example, in an open hole. Similarly, the provision of such back up systems 230,250 are of benefit in high temperature environments where the sealing elements 220,240 may soften and be inclined to extrude under pressure into the annulus (not shown). The metal layers 286,288 provide support for the sealing elements 220,240 to prevent extrusion.
The ring member 260 defines a first sealing element deforming portion 290 and a second sealing element deforming portion 292. These portions 290,292 assist in the initial deformation of the sealing elements 220,240 when a larger annulus has to be bridged. In the sealing apparatus 210 of
Referring to
As will be noted from
Referring now to
An alternative method of providing an initial deformation of the sealing elements 220,240 of
In this Figure only one sealing element 320 is shown. A single sealing element arrangement could be used to seal from only one direction or another sealing element could be added to seal from the opposite direction to the first sealing element 320 as well.
In this embodiment, a collapsible sleeve 301 is provided behind the sealing element 320. The sleeve 301 comprises a cylindrical tubular defining a plurality of slots 303. The sleeve 301 also includes three circumferential grooves 304,305,306. The grooves 304,305,306 are points of weakness of the sleeve 301, and the application of a compressive force will cause the sleeve 301 to deform at these points of weakness 304,305,306 resulting in a sleeve centre portion 307 bowing radially outwards to deform the sealing element 320.
Various modifications can be made to the described embodiments without departing from the scope of the invention. For example, the ring member 60 is described as an H section, it will be understood that any suitable section could be used. Similarly although the collars 26,46 have threaded portions 28,48 for attaching to tools or tubulars, collars could be attached to tools or tubulars by any suitable means, such as being pinned.
With regard to
Number | Date | Country | Kind |
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0622241.8 | Nov 2006 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2007/004177 | 11/2/2007 | WO | 00 | 12/15/2009 |