Embodiments disclosed herein generally relate to a method for controlling the injection of actuators such as balls into a wellbore, such as drop balls, frac balls, and packer balls, for interacting with downhole tools, such as those used for actuating tools that allow select zones or zone intervals in the wellbore to be stimulated. More particularly, the embodiments include supporting balls in a carrier medium for transport in a conventional fluid stream to their respective downhole destinations.
It is known to conduct fracturing or other stimulation procedures in a wellbore by isolating zones of interest, or intervals within a zone, in the wellbore, using packers and the like, and subjecting the isolated zone to treatment fluids, including liquids and gases, at treatment pressures.
In a typical fracturing procedure for a cased wellbore, for example, the casing of the well is perforated to admit oil and/or gas into the wellbore. Fracturing fluid is then pumped into the wellbore and through the perforations into the formation. Such treatment opens and/or enlarges drainage channels in the formation, enhancing the producing ability of the well. For open holes that are not cased, stimulation is carried out directly in the zones or zone intervals.
It is typically desired to stimulate multiple zones in a single stimulation treatment, typically using onsite stimulation fluid pumping equipment. A series of packers in a packer arrangement is inserted into the wellbore, each of the packers located at intervals for isolating one zone from an adjacent zone. It is known to introduce a ball into the wellbore to selectively engage one of the packers in order to block fluid flow therethrough, shift a sleeve to open ports for treatment or stimulation of an isolated zone uphole from a packer. Once the isolated zone has been stimulated, a subsequent ball is dropped to block off a subsequent packer, uphole of the previously blocked packer, for isolation and stimulation thereabove. The process is continued until all the desired zones have been stimulated. Typically, the balls range in diameter from a smallest ball, suitable to block the most downhole packer, to the largest diameter, suitable for blocking the most uphole packer.
At surface, the wellbore is fit with a wellhead including valves and a pipeline connection block, such as a frac head, which provides fluid connections for introducing stimulation fluids, including sand, gels and acid treatments, into the wellbore. Conventionally, operators manually introduce balls to the wellbore through an auxiliary line, coupled through a valve, to the wellhead. The auxiliary line is fit with a valved tee or T-configuration connecting the wellhead to a fluid pumping source and to a ball introduction valve. The operator closes off the valve at the wellhead to the auxiliary line, introduces one ball and blocks the valved T-configuration. The pumping source is pressurized to the auxiliary line and the wellhead valve is opened to introduce the ball. This procedure is repeated manually, one at a time, for each ball.
Other alternative methods and apparatus for the introduction of the balls have included an array of remote valves positioned onto a multi-port connection at the wellhead with a single ball positioned behind each valve. Each valve requires a separate manifold fluid pumper line and precise coordination both to ensure the ball is deployed and to ensure each ball is deployed at the right time in the sequence, throughout the stimulation operation. It is known to feed a plurality of perforation-sealing balls using an automated device as set forth in U.S. Pat. No. 4,132,243 to Kuus. Same-sized balls are used for sealing perforations and are able to be fed one by one from a stack of balls. The apparatus appears limited to same-sized balls and there is no positive identification whether a ball was successfully indexed from the ball stack for injection. In another prior art arrangement, such as that set forth in
Applicant introduced a radial ball injector in U.S. Pat. No. 8,136,585, issued Mar. 20, 2012, the injector having a housing adapted to be supported on the wellhead. Each radial housing has an axial bore and at least one radial ball array having two or more radial bores extending radially away from the axial bore and fluidly connected therewith. The axial bore is aligned with the wellbore. Each radial bore houses a ball cartridge. Each radial bore has an actuator for actuating the ball cartridge. The ball cartridge is movable along the radial bore for extending into and retracting from the axial bore. The ball cartridge receives, stores, and releases balls. More than one radial ball array can be vertically stacked one on top of another to increase the number of balls available for wellbore operations. A radial ball array can be housed in a radial housing. Alternatively, more than two radial ball arrays can be vertically arranged within a radial housing. In each case, the axial bore of each of the radial housing is aligned with one another and with the wellbore.
Regardless of the means for introducing the ball, an operator cannot be assured of the ball's successful introduction to the wellbore, or the timing in which the ball reaches the downhole tool, or the safety and integrity of the ball.
As the majority of the sand-laden fracturing fluids are introduced at the frac head below the ball injectors, there can be an accumulation of sand formed in the bore at the interface of the ball injector and the frac head.
Typically, to reduce the effect of direct impingement of the fracturing fluid on the frac head, frac fluid can be introduced to the frac head from opposing inlets. As these high velocity fluid streams impact one another in the main bore of the frac head, a vortex of fracturing fluid can be created in an upper portion of the bore, which can result in an accumulation of sand or other particulates at the injector, the accumulation potentially impeding ball injection.
Further, as shown in
As a result, balls can be impeded from entering the wellbore, and for those balls that do successfully enter the wellbore, these can be impeded from reaching their desired and intended location, such as downhole tools.
Further, it is not uncommon for a ball to be damaged or to disintegrate enroute or upon arrival at the downhole tool requiring a replacement ball or one of the same diameter to be launched again. Some apparatus requires depressurization and reloading of balls. This requires time consuming and properly managed procedures to maintain safe control in a hazardous environment and to complete testing and re-pressurization procedures upon reinstallation to the wellhead. The pumping of displacement fluid, such as fracturing fluid, through the ball injector unit can also damage or scar balls, especially if the displacement fluid is sand-laden fracturing fluid. Damaged and scarred packer balls typically fail to isolate the zone requiring an operator to then drop an identical ball down the bore of the injector.
Some injector apparatus, lacking backup balls, can require the entire unit to be removed, the replacement ball dropped, the unit reassembled, and pressure tested. This is extremely inefficient, time consuming, costly and can adversely compromise the treatment. Some methods require several balls to arrive at a multi-port packer basically at the same time. In such a multi-port packer, if some ports close and one of the multi-port remains open, the increased surge of fluid travelling therethrough will erode the orifice very quickly.
Further, other actuators such as a dart and the like are also dropped into a wellbore for actuation of various tools such as packers, landing nipples and circulation subs.
There remains a need for a methodology for delivering dropped balls safely and reliably downhole.
Generally, as described herein, free-falling actuators, such as balls and darts are conveyed downhole, supported in a carrier medium like a sabot. Delivery of the carrier medium and actuator is controlled by control of a displacement fluid. The carrier medium protects the actuator, or actuators carried therein, and ensures a predictable arrival of the actuator at the tool, predictable both in arrival time and actuator integrity.
In one aspect, a method is provided for delivering at least one actuator, such as a ball, to a downhole tool positioned a wellbore, comprising supporting the at least one ball with a carrier medium, and pumping a displacement fluid into the wellbore for transporting the carrier medium and the supported at least one ball down the wellbore to the downhole tool.
In one aspect, the carrier medium is provided as a slug, the actuator being supported on or within the slug.
In another aspect the actuator is retrieve at a catcher at surface, the actuator supported still by the carrier medium.
As described herein, free-falling actuators, such as drop balls, frac balls, packer balls, darts and other actuators, are generally released into a wellbore for falling through wellbore fluid, pumped or otherwise being conveyed to a downhole tool, for interacting therewith, such as to actuate the tool's function. In the prior art, the actuator is released and is subject to the vagaries of the wellbore environment including the wellbore itself, obstructions and fluid characteristics. Herein, the actuator is supported by a carrier, the carrier being a medium such as a gel of other supporting structure acting like a sabot for safe delivery of the actuator to a destination. The delivery of the carrier medium and actuator is dictated by the flow and control of a displacement fluid down the wellbore. The carrier medium supports the ball so that the displacement fluid is the actor causing transport of the ball downhole; basically when the fluid flow stops, the medium and supported ball stops. The carrier medium protects the actuator or actuators carried therein and ensures a predictable arrival at the tool, predictable both in arrival time and actuator integrity. Further, during retrieval, the carrier medium aids to space successive ball returns and in avoid ball jams. Herein the actuator is typically referred to in the context of ball injectors and ball although darts and other actuators that are dropped into a wellbore can benefit equally from the methodologies employed herein.
As shown in
In a conventional hydraulic fracturing or “frac” operation, a fracturing fluid F is injected downhole into the wellbore 10 through two opposing side fluid ports 20,20 of the frac head 14. Downhole tools, such as sliding sleeves, are designed to pass fluid therethrough until the receipt of an actuator such as a ball, which blocks a port in the sleeve. Fluid pressure releases and shifts the blocked sleeve to open ports and access the formation outside the wellbore 10.
In the prior art, the ball 16 falls through the fluid F and the fluid can be pumped to aid the ball's transport downhole. The release, transport and receipt of the ball can be adversely influenced by the fracturing fluid and by the wellbore characteristics between the release and receipt of the ball. Adverse influences include the unknown fall rate of the ball through the fluid and buildup of fracturing sand in eddies and low spots in the wellbore. At the wellhead it is believed that the vortex of opposing streams of incoming fracturing fluid at the frac head 14 resulting in an accumulation of sand in dead-spots. Temporary bridges 22 can form at normally-dead flow zones, above the side inlet ports 20,20, which can impede ball injection into the wellbore 10. Further, and with reference to
Accordingly, to overcome this or other difficulties encountered in injecting balls downhole discussed below, an actuator carrier medium 32 is introduced to at least travel in advance of the actuator for support and transport of the actuator past trouble spots and at a predicable rate dictated by the volume of displacement fluid delivered downhole.
Returning to
The carrier medium 32 is a structure sufficient to support the ball 16 therein or thereabove. A deformable structure, such as a foam, viscous fluid or gel has the structure necessary to support a ball and yet be driven down and back up a wellbore using a displacement fluid. Foam plugs or pigs are known in the pigging industry for swabbing or cleaning tubular components. A foam pig is transported by a displacement fluid. The carrier medium 32 can be a slick gel as is known in the fracturing art. A gel form of carrier medium 32 can be complexed or formed as viscous or dense as necessary to maintain the ball suspended therein so as move substantially as a whole during transport. Those of skill in the art can ascertain the carrier medium characteristics suitable so as to support a ball of known mass and dimensions in suspension. The ball 16 is supportably retained upon or in the carrier medium 32 during transport through the wellbore 10 to a downhole tool.
At least a portion of the slug 30 of carrier medium 32 is positioned downhole of the injection point 34 and the ball 16 is injected into or above the carrier medium 32. An additional slug 20 or slugs of carrier medium 32 can be introduced after the ball 16 is injected. The carrier medium 32 protects and supports the ball 16 from at least below the ball 16, or even encapsulating the ball 16 therein. The positioning of the slug 30 of carrier medium 32 can be manipulated by the use of the introduction of displacing fluids and valve operation. In fracturing operations, where fracturing fluids are pumped substantially continuously downhole, a pressure-balanced bore 38 of the injector 18 and wellbore 10 is established and a slipstream of the carrier medium, ball and chase fluid is applied to introduce the slug to the fracturing fluid. When introduced, the fracturing fluid F displaces the slug downhole. The flow of fracturing fluid is typically reduced temporarily during ball injection which also assists in maintaining the integrity of the slug 30 for conveyance downhole as a whole, downhole.
The slug 30 of carrier medium 32 and at least one ball 16 are injected into the wellbore 10 by pumping the displacement fluid F from uphole of the slug 30, driving the carrier medium 32 and supported ball 16 downhole. As shown, the carrier medium 32 and ball 16 can initially be jockeyed to a position downhole of the frac head. Pumped displacement fluid F, such as fracturing fluid, is used to displace the slug 30 downhole to the downhole tool. The carrier medium 32, under the influence of the displacement fluid F, travels with and ahead of the ball 16 for managing ball transport including: controlling the transport velocity of the ball, protecting the ball, and ensuring that a portion of the wellbore 10 ahead of the injected ball 16 is substantially unimpeded by accumulations or movable obstructions.
In the case of a gel slug, the dedicated pump 44, such as a positive displacement pump, can inject a sufficient volume of gel necessary to support or surround the ball 16. Alternatively, the pump 44 can inject a complexing additive sufficient to cause gelling of a passing base fluid, timed to intercept an injected ball 16 at the injector 18.
In an embodiment, the bore 38 of the ball injector 18 is isolated from the wellbore 10 and the carrier medium 32 and ball 16 are introduced. In an alternate embodiment, the injector is open to the wellbore and the carrier medium is introduces under wellbore conditions. A first block or volume of the carrier medium 32 is introduced into the bore 38, such as from about a port 42 or top 46 of the injector 18, forming the axially-extending slug. The slug 30 is positioned, re-positioned or traverses at least below about the injection point 34 of the ball 16, through the manner of injection, timing or fluidly repositioned thereafter. The slug 30 can fill the bore 38 to about the isolation valve 40 which separates the bore 38 of the ball injector 18 from the frac head 14. The ball 16 can be injected into the bore 38 for positioning and support somewhere between an uphole end of the slug or intermediate therein. In an embodiment, the slug 30 can envelope or encapsulate the ball 16 therein such as by injecting the ball 16 intermediate the slug or by adding a second volume of carrier medium, after ball injection, above the first block or volume. A carrier medium or structure, deformable and pumpable downhole, also accepts injection of a ball therein.
The slug 30 of carrier medium and ball 16 therein is moved from the injector 18 and into the wellbore 10, for displacement downhole. If not open already, the bore 38 is opened to the wellbore 10 and the slug is displaced from the injector 18 and into the wellbore. The slug 30 of carrier medium 32 is displaced from the injector 18 such as by the addition of fluid from the pump 100, a slipstream or bypass stream of frac fluid F through bypass line 45, or other fluid means. Alternatively, gravity, a hydraulic plunger or mechanical device can be used to urge the slug of carrier medium 32 and supported ball 16 out of the injector 18 and into the wellbore 10.
With reference to
In operation, and with reference to
In more detail, and returning to
With reference to
As shown in
The position of the slug 30 in the system can be determined using the measured volume of the displacement fluid F and the cumulative displacement volume of the system. A lineal volume of the wellbore 10, per lineal depth, and cumulative displacement volume of the system is established. A measured volume of displacement fluid F is pumped into the wellbore. One compares the measured volume of displacement fluid and a cumulative displacement volume of the wellbore to locate the ball carrier medium and the supported at least one ball along in the wellbore.
In an embodiment, the carrier medium 32 is a complexed gel commercially available for use in the oil and gas industry, which is injected or complexed at the ball injector 18 by the separate dedicated pump 44 (
Referring back to
As shown in
In the prior art, a ball 16 would fall at an estimated rate, or could get hung up at obstructions, low spots including sand accumulations. Depending on fracturing fluid flow, density, viscosity and ball density, the balls may arrive downhole faster or slower than estimated. In the instance where the ball is anticipated to actuate a device, typically fracturing fluid flow is slowed just before arrival to lessen impact. If, however, the estimate is incorrect, a slackening of flow rate maybe too late to avoid impact or collision damage to the ball or downhole device.
Instead, using embodiment described herein, the arrival of the slug 30 and associated ball 16 can be precisely determined knowing the bore dimension and fracturing fluid volumes pumped. Further, the arrival time and positioning of low density or “floating” balls and regular density balls can be equally controlled with precision. Knowledge of the location of the ball 16 during transport permits an operator to reduce the velocity of the pumped displacement fluid F as the slug 30 approaches the downhole tool, minimizing the potentially damaging forces of impact of the ball and the tool.
Further, in devices utilizing multiple like-sized balls 16,16 . . . per device, such as a multi-port tool or packer having multiple ball seats, all of the balls for that device can be support on or encapsulated within in a single slug 30. Therefore in the case where it is desirable for several balls 16,16 to arrive at a multi-port packer at about the same time, the multiple balls can be transported in a tight cluster. Thus, open port erosion is minimized or eliminated by ensuring all ports are blocked at substantially the same time. Further, in either single or multi-port devices, the passage of a portion of the slug 30 through the port can aid in cleaning the port or orifice seat from remnants of sand thus creating a better seal face for the packer ball to seat and seal against. Use of a heavy gel-like carrier medium may also aid in the sealing ability.
In a further embodiment, and as shown in
The slug 30 support the ball 16 and assists in a staged recovery of the balls 16 up the wellbore 10, for entrainment and recovery, despite a reverse order of the balls. In the prior art, on recovery, earlier released balls, being lower in the wellbore, and smaller unrestrained balls, had a tendency to jam against larger balls higher in the wellbore, creating a cluster or ball jam at surface equipment. Such ball jamming is quite common with some balls not being recovered at all. Clearing ball jams requires shutting down the fluid flow back, and the resulting time delay caused balls and remnants of sand to drop out which can potentially create sand bridge plugs which then would require potentially costly coil tubing intervention to cleaning out jammed balls and sand accumulation.
Instead, using slugs 30 of carrier medium, each ball 16 is recovered with its respective slug 30, the transport and recovery order being independent of the size of ball 16, each slug acting to maintain separation of successive balls and avoiding jams.
This application claims the benefits under 35 U.S.C 119(e) of U.S. Provisional Application Ser. No. 61/504,291, filed Jul. 4, 2011, which is incorporated fully herein by reference.
Number | Date | Country | |
---|---|---|---|
61504291 | Jul 2011 | US |