1. Field of the Invention
The present invention relates to well equipment for use in the oil and gas industry, in particular to a trigger mechanism for a ball activated device.
2. Background Art
In order to produce hydrocarbons, i.e. oil and gas, a borehole is drilled through several layers of rock in a formation. Hydro carbons may be present in a zone comprising a layer of porous rock under a layer of non-porous rock. Several such zones can be present along the borehole. The borehole may extend horizontally along one or more zones. All or part of the borehole can be lined by a steel casing or liner cemented to the rock to form a wellbore. One or more production strings can be inserted into the wellbore. As used herein, the term ‘tubing’ means any casing, liner or production string having a central bore through which a fluid may flow. Different tubings are provided with various devices such as valves, loggers, plugs, packers etc. in order to complete the well or to control the production from the different zones as known in the art.
One or more injection wells can be provided in a similar manner. An injection well is typically used to increase the pressure in a remote part of a zone to force the hydro carbons in the direction of a production well and thereby increasing the production.
The devices in the well can be operated in a number of known manners, including by so-called drop balls. A ball activated device is included in a tubing, and comprises a ball seat which forms a fluid tight obstruction with a drop ball of a suitable size. When it is desired to activate the device, the drop ball is dropped or pumped down within the tubing until it lands on the ball seat. Then, pressure is applied behind or upstream from the ball. When the force exerted by the pressure on the piston area exceeds a predetermined level, the ball seat shifts downstream and activates the device, for example by shifting a sliding sleeve valve from a closed position to an open position. In a cementing operation cement can then be pumped through the open valve into an annulus behind the casing, e.g. between the casing and the formation. In a fracturing operation, fracturing fluid with suitable proppants can be pumped through the open valve.
As known in the art, any suitable object can be dropped or pumped down the well to prevent fluid flow through a seat. The terms ‘ball’ and ‘ball activated’ are used for simplicity, and the term ‘ball’ should be regarded as any object capable of blocking a flow as discussed above.
In some wells, several ball activated devices are provided with seat diameters that decrease with the distance from the surface, which is termed the downstream direction in the present disclosure. To activate the ‘deepest’ device, i.e. the device furthest away from the surface, the smallest of a plurality of balls is pumped down and passes all the larger seat diameters before lodging or landing on the last seat. Thereafter, successively larger balls are used to activate the devices closer to the surface.
For simplicity, a sliding sleeve valve is used to illustrate a ball activated device in the following description. However, it should be understood that the ball activated devices considered in the present invention are not limited to sliding sleeve valves. For example, a linear motion is easily transformed to a rotation using helical shoulders between two sleeves or a rack and gear arrangement. Thus, an axially moving seat may turn an element around its axis, e.g. a ball in a ball valve or a plate in a butterfly valve.
U.S. Pat. No. 4,360,063 A (Kilgore) discloses a slide valve with a ball seat comprising lugs on collet fingers defing a ball seat. When it is desired to close the valve, a ball is dropped into a tubing and pressure is exerted to move the ball downward and close the slide valve. When the valve closes, the lugs expand into a groove and permit the ball to fall through the slide valve member. The lugs hold the slide valve in closed position. The spaces between the lugs on the collet fingers may be dimensioned to be of close tolerance or provided with resilient material to restrict or prevent flow therethrough and/or the ball may be made of resilient material or have a hard core with a resilient cover to inhibit or prevent flow of fluid through the collet fingers when the ball is seated on the fingers. In this manner, one ball can lodge on several seats, all having the same diameter, and activate corresponding valves one by one.
In U.S. Pat. No. 4,360,063 the seat is affixed to the sliding sleeve. Thus, the force exerted on the ball and seat must be sufficient to overcome an initial retaining force keeping the sliding sleeve open plus a friction force between the entire sliding sleeve and the surface within which it slides all at once. This friction force can be significant, in particular if the slide valve has been exposed to aggressive and/or contaminated well fluids for an extended period of time. Further, before the ball lands on the seat, particles in the well fluids or scaling may deposit in the groove into which the lugs are supposed to expand. If the lugs do not expand radially, the ball is prevented from passing through and the intended operation fails.
U.S. Pat. No. 8,215,401 B2 (Braekke et al.) discloses a collet configured to slide axially within an inner sleeve, which in turn is configured to slide axially within an outer sleeve. The collet comprises longitudinal fingers. Initially the fingers form a ball seat and the collet is retained by a first release mechanism designed to release the collet from the inner sleeve when a first pressure exceeds a predetermined level. A second release mechanism is designed to release the fingers when the device is activated, e.g. when the valve has shifted from an initially closed to a final open state. Once released, the fingers flare out in order to permit the ball to pass.
One problem with the expandable seat of U.S. 8,215,401 B2 is the need for a second pressure greater than a first pressure in order to release the second release mechanism after the to first release mechanisms to ensure proper operation of the device. In some applications, it might be advantageous to activate a device once a predetermined pressure is reached, and still be guaranteed that certain steps between the initial and final states are performed in a predetermined sequence to ensure proper transition from the initial to the final state.
Further, the collet fingers in U.S. 8,215,401 B2 are preferably spaced apart such that one collet can be configured to a desired ball seat diameter by mounting suitable lugs between the distal ends of the fingers and the surface in which the collet slides. However, in applications where a fluid containing particles, e.g. in cementing or fracturing operations, particles such as sand or proppant may enter between the fingers and settle behind them such that they do not flare out to let the ball pass.
In one embodiment disclosed in U.S. Pat. No. 8,215,401 B2, the first release mechanism comprises a head intended to slide over a small stopping shoulder. This head may require a space between two sleeves into which sand or proppant may enter. In general, particles may enter spaces between or behind sleeves and prevent proper operation of the expandable ball seat.
In other applications, an expandable ball seat is designed to stay in a production string for an extended period of time before being activated. In such applications, scaling and/or corrosion may cause similar problems. For example, scaling may build up between the sleeves or in exposed grooves and prevent the sleeve from moving axially or the ball seat from expanding radially. Corrosion may affect mechanical parts such as exposed shear pins or helical shoulders required for transforming a linear motion into a rotation. Hence scaling and corrosion might prevent proper operation of the trigger mechanism and/or the ball operated device triggered by the mechanism.
An object of the present invention is to solve at least one of the problems above.
This is achieved by a trigger mechanism for a ball activated device according to claim 1.
In particular, a trigger mechanism for a ball activated device comprises an inner sleeve axially slidably disposed within an outer sleeve from an initial state wherein the ball activated device is inactive to a final state wherein the ball activated device is activated. A seat sleeve is axially slidably disposed within the inner sleeve. The seat sleeve comprises radially moveable seat defining members configured to form a fluid tight seal with a ball in the initial state and allowing the ball to pass in the final state. The trigger mechanism is distinguished in that an alternating member is disposed radially moveable in a radial aperture through a wall of the inner sleeve, wherein the alternating member: abuts an upstream side of a first axial stopper on an inner surface of the outer sleeve and a radially exterior surface on the seat sleeve in the initial state, is received in a recess on the seat sleeve in an intermediate state, and is received in a groove in the inner surface in the final state.
Thus, first the seat sleeve shifts axially within the inner sleeve in order to align the recess on its exterior surface axially with the alternating member extending through the wall of the inner sleeve. Once the alternating member has entered into the recess in the seat sleeve, it may pass the first axial stopper on the inner surface of the outer sleeve such that the inner sleeve can start sliding axially within the inner surface. Once the inner sleeve has moved a predetermined axial distance within the outer sleeve so that the ball activated device is activated, the alternating member moves radially outward into a groove in the inner surface of the outer sleeve. The predetermined axial distance can e.g. be determined by a first complementary axial stopper disposed upstream from the first axial stopper in the initial state.
Once the alternating member is out of the recess in the outer surface of the seat sleeve, the seat sleeve is permitted to proceed further within the inner sleeve until the seat defining members are out of the inner sleeve and thereby allowed to flare out radially in order to permit the ball to pass in the final state. In the final stage, the seat sleeve is prevented from leaving the inner sleeve by a second pair of axial stoppers on the seat sleeve and inner sleeve respectively.
Before and during the above series of events, the alternating member, the recess and the groove in which the alternating member is received are disposed between the seat sleeve and the inner surface at all times. Further, as the seat and ball needs to form a fluid tight unit in order for an activating pressure to build up behind the ball, well fluids cannot enter into the spaces between and behind the sleeves. In other words, the alternating member, recess and groove are protected from well fluids with particles and/or well fluids causing corrosion and scale deposits all of which might prevent or inhibit the radial motion of the alternating member.
In a preferred embodiment, the spaces between and behind the sleeves are filled with an incompressible water-repelling fluid kept at the pressure of the surrounding well fluid. For example, the spaces within the trigger mechanism may be filled with grease, petroleum jelly or liquid mineral oil which are contained by seals and the pressure may be equalized with bellows, membranes or piston arrangements in any known manner. When the fluid within the mechanism is kept at the same pressure as the surrounding well fluids, there can be no pressure difference to force the well fluids into the spaces behind the sleeves and cause aqueous emulsions within the trigger mechanism. In particular, water with dissolved carbonate is prevented from entering, whereby scaling and corrosion is prevented.
In some embodiments, the alternating member is radially biased. A biased member may be combined with a protrusion such as a shoulder to retain a sleeve, as the bias must be overcome before the alternating member can pass the protrusion. Thus, a biased alternating member and protrusions may provide an alternative or supplement to shear pins and other known retainers in the art, for example to retain the seat sleeve in the initial state.
Some embodiments further comprise a temporary axial stopper and a complementary member configured to temporarily halt the axial motion of the seat sleeve at a position wherein the alternating member can enter the recess. Without the temporary axial stopper and complementary member, the recess on the seat sleeve might race past the alternating member such that the inner sleeve would still be retained in the un-shifted position while the seat sleeve proceeds within the inner sleeve and perhaps even releases the ball. If the inner sleeve remains in the initial position, the ball activated device remains inactive.
In some embodiments, an inner surface of the seat sleeve further comprises key grooves configured to receive a fishing tool. In these embodiments a fishing tool, e.g. provided on a slick line, can engage the key grooves and be used to pull the trigger mechanism back to the initial state.
In embodiments of the present invention, the seat defining members can comprise axially extended collet fingers disposed in close contact with each other around the circumference of the seat sleeve. This feature primarily prevents particles in the well fluid from entering the space behind the collet fingers. For this, the term ‘close contact’ defines a space between the fingers which is less than a predetermined minimum particle size. In addition or alternatively the collet fingers may form part of the fluid tight seat required to allow pressure to build up upstream from a lodged ball. Further, it should be understood that the seat defining members do not necessarily comprise collet fingers. For example, seat defining members arranged to slide radially in or on a guide affixed to a rigid seat sleeve might be used in other embodiments.
In some embodiments a protective sleeve may be arranged such that it extends axially from the seat sleeve over an area receiving the seat defining members in the final state. The protective sleeve primarily prevents debris, particles or scaling from entering or building up in grooves or a reduced diameter into which the seat defining member are moved in the final state in order to let the ball pass. Obviously, if scaling or debris prevents the seat defing members from moving outward, the ball will not pass through in the final state and the trigger mechanism will not work in the intended manner.
These and other features and advantages of the invention are defined in the claims, and will become apparent from the detailed description below.
The invention will be described in greater detail using specific embodiments and with reference to the accompanying drawings in which:
In the description of
In
In
An inner sleeve 120 is releasably retained within an inner surface 101 by a radially moveable alternating member 125 engaging a shoulder 112 on the inner surface 101. When released, the inner sleeve 120 is free to slide axially within the inner surface 101 until a radially extending shoulder 122 on the inner sleeve abuts a complementary shoulder 112 on the inner surface 101. The initial distance between shoulders 112 and 122 must be sufficient to allow the upsteam edge of sleeve 120 to pass the ports 105 in order to open the slide valve, or in general to activate the ball activated device.
A seat sleeve 130 is releasably retained within the inner sleeve 120 by shear pins 135 designed to break at a predetermined force. When released, the seat sleeve 130 is free to slide axially within the inner sleeve 120 until a radially extending shoulder 133 on the seat sleeve 120 abuts a complementary shoulder 123 on the inner sleeve 120. It is understood that the initial distance between shoulders 123 and 133 must be sufficient to allow the seat defing member 132 to slide out of the inner sleeve 120 such that they are no longer supported and thereby allowed to move radially outward in order to let the ball 300 pass between the members 132 in the final state shown in
The trigger mechanism of the invention comprises an aperture 124 extending radially through the wall of the inner sleeve 120. The alternating member 125 is disposed in the aperture 124, and can move radially inward or outward as it travels axially along a profile. In the initial state in
A recess 134 in the outer surface of the seat sleeve 130 is disposed upstream from the alternating member 125 in the initial state shown in
In
In other words, the seat defining members 132 still form a ball seat in the intermediate state. The force exerted on the ball 300 and seat formed by the seat defing members 132 is transferred to the inner sleeve 120 through the alternating member 125 such that the seat sleeve 130 pulls the inner sleeve 120 downstream. Thus, in the embodiment illustrated in
In
As the alternating member 125 is received in the groove 114,
In the final state shown on
A variety of seat configurations are known to provide a fluid tight seal permitting a pressure to build up behind a lodged ball. For example, the prior art documents U.S. Pat. No. 4,360,063 and U.S. Pat. No. 8,215,401 both exhibit seats comprising collet fingers with spaces between each finger. In the embodiment on
In general, the design must be adapted to the operation at hand. For example, a trigger mechanism according to the invention designed for a cementing or fracturing operation would advantageously be designed such that particles of the sizes involved do not pass between the elements of the seat sleeve 130 under the pressures employed during the operation.
From the above discussion of
In a preferred embodiment, the spaces between and behind the sleeves, including the aperture 124 and groove 114, are filled with filled with an incompressible, water-repelling fluid kept at the pressure of the surrounding well fluid.
Seals between the sleeves are omitted from the figures for clarity. However, it is understood that conventional seals similar to the seals 127, 128 of the ball activated device, for example O-rings supported in a conventional manner, must be provided to ensure a fluid tight connection such that a pressure may be built up behind the ball 300. Conversely, if fluid was allowed to pass through or between the sleeves, a pressure could not build up in order to exert an axial force on the lodged ball. It is considered within the capabilities of the skilled person to provide seals suitable for this purpose as well as any additional seals required for keeping a clean, incompressible fluid within the spaces behind and between the sleeves. In particular, liquid filled spaces prevent particles and water containing dissolved carbonates from entering, and thereby prevent deposits of particles and/or scaling from forming. When water influx is inhibited or prevented, corrosion is also inhibited or prevented.
Suitable incompressible fluids are water-repelling liquids such as grease, petroleum jelly or mineral oil. The specific carbon numbers will depend on the expected pressure and temperature in the well. In addition to prevent liquid from escaping from the spaces within the trigger mechanism, the seals prevent well fluids from entering into the spaces.
Pressure equalizers are advantageously provided to minimize the pressure difference, and hence the driving force, from the ambient well fluid to the interior of the trigger mechanism. For example, a bellow, membrane or piston might be provided to equalize the pressure within the trigger mechanism with the ambient pressure in the well. Such pressure equalizers are known in the art, and are not described further herein.
In the embodiment with collet fingers 131 illustrated in
In a still further preferred embodiment, a protective sleeve 150 extends axially from the downstream end of the seat sleeve to a downstream part of the tubing 200. In the initial state on
In
In
In
To ensure that the alternating member 125, 126 enters into the recess 134 at a predetermined displacement L, a pin 1250 connected to the inner sleeve 120 is axially slidably disposed in a longitudinal groove 138 on the seat sleeve 130. In the initial position shown on
When the seat sleeve 130 is displaced nearly a distance L downstream, i.e. toward the right in
Generally, any radially protruding element on a first sleeve engaging a complemetary member on a second sleeve could stop the relative axial movement between the first and second sleeves. In the claims, the terms ‘axial stopper’ and ‘complementary member’ denotes one such pair of elements designed to prevent or inhibit motion between two sleeves. In the description above, stopping shoulders 112, 122 and 123, 133; shoulders 133, 137 agains roller 126; alternating member 125 in groove 114 and pin 1250 in longitudinal groove 138 are examples of such pairs. Further varieties, e.g. providing the groove 138 on the inner sleeve 120 and the pin 1250 on the seat sleeve 130, are considered obvious. A practical design of axial stoppers and complementary members is left to the skilled person.
In the drawings, some recesses and grooves are depicted without inclined shoulders to illustrate the invention as clearly as possible, i.e. without unnecessary details. However, the recesses or grooves can be provided with inclined surfaces to facilitate entry and/or exit of a complementary member such as the lug 125 or roller 126 described above. In particular, it is noted that the activating sequence shown in
Next, assume that the ball activated device 100 in
According to the present invention, the different parts are released in sequence rather than all at once. First, the friction forces sticking the seat sleeve 130 to the inner surface 120 (plus the force required to break the shear pins 135 in
When the seat sleeve 130 has shifted downstream a distance L within the inner sleeve 120 as depicted on
For trigger mechanisms designed to stay in a well for an extended period of time, it might be advantageous to make the area of the seat sleeve 130 exposed to the well fluids small compared to the exposed area of the inner sleeve 120 and also in comparison to the exposed area of an optional protecting sleeve 150, because a smaller exposed area decreases the amount of deposits that might cause the seat sleeve 130 to stick. The area of the seat sleeve can, for example, be decreased by using pins on the seat sleeve 130 and longitudinal grooves on the inner sleeve as axial stoppers/complementary members. Also, the collet fingers 131 and members 132 shown in
The alternating member 125 in
On
Pins 433 sliding in longitudinal grooves 423 provide an alternative means for limiting the relative motion between the inner sleeve 120 and the seat sleeve 130. That is, the pins 433 in the grooves 423 serve the same purpose as the shoulders 123 and 133 on
Similar pins 1250 in grooves 138 stops the axial motion of the seat sleeve 130 within the inner sleeve 130 temporarily to ensure that the alternating member 125 enters the groove 134 properly as discussed in connection with
An optional leaf spring 435 is shown on
In the initial state on
On
In addition to guide(s) 129 centering the inner sleeve 120 within the inner surface 110, a seal 429 is provided in the embodiment on
The distal or downstream ends of the collet fingers 131 interlock with the upstream end of the protective sleeve 150 in a castellation 140. The castellation 140 prevents relative rotation between the seat sleeve 130 and the protective sleeve 150, and permits the seat defining members 132 to flare outward into the seat receiving recess 115 when the trigger mechanism 100 reaches its final state.
The means on
When the pins 1250 shown on
Various other embodiments of the invention will be apparent to those skilled in the art reading the description above. However, the invention is not limited to the specific exemplary embodiments above, but is defined by the subject matter set forth in the appended claims.
Number | Date | Country | Kind |
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20130777 | Jun 2013 | NO | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2014/001164 | 6/6/2014 | WO | 00 |