US20150068772A1 - Downhole Ball Dropping Systems and Methods with Redundant Ball Dropping Capability - Google Patents
Downhole Ball Dropping Systems and Methods with Redundant Ball Dropping Capability Download PDFInfo
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- US20150068772A1 US20150068772A1 US14/446,918 US201414446918A US2015068772A1 US 20150068772 A1 US20150068772 A1 US 20150068772A1 US 201414446918 A US201414446918 A US 201414446918A US 2015068772 A1 US2015068772 A1 US 2015068772A1
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B34/00—Valve arrangements for boreholes or wells
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B23/00—Apparatus for displacing, setting, locking, releasing, or removing tools, packers or the like in the boreholes or wells
- E21B23/04—Apparatus for displacing, setting, locking, releasing, or removing tools, packers or the like in the boreholes or wells operated by fluid means, e.g. actuated by explosion
- E21B23/0413—Apparatus for displacing, setting, locking, releasing, or removing tools, packers or the like in the boreholes or wells operated by fluid means, e.g. actuated by explosion using means for blocking fluid flow, e.g. drop balls or darts
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B47/00—Survey of boreholes or wells
- E21B47/09—Locating or determining the position of objects in boreholes or wells, e.g. the position of an extending arm; Identifying the free or blocked portions of pipes
- E21B47/092—Locating or determining the position of objects in boreholes or wells, e.g. the position of an extending arm; Identifying the free or blocked portions of pipes by detecting magnetic anomalies
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B47/00—Survey of boreholes or wells
- E21B47/12—Means for transmitting measuring-signals or control signals from the well to the surface, or from the surface to the well, e.g. for logging while drilling
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- E21B2034/002—
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/02—Subsoil filtering
- E21B43/04—Gravelling of wells
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Abstract
A downhole ball dropping system operable to be positioned in a well. The system includes a tool string having a flow path. First and second ball dropper assemblies are interconnected in the tool string. The first ball dropper assembly releasably retains a first ball and the second ball dropper assembly releasably retains a second ball. A sensor is operable to detect deployment of the first ball and is operable to generate a signal to prevent release of the second ball from the second ball dropper assembly.
Description
- This application claims the benefit under 35 U.S.C. §119 of the filing date of International Application No. PCT/US2013/058952, filed Sep. 10, 2013.
- This disclosure relates, in general, to equipment utilized in conjunction with operations performed in relation to subterranean wells and, in particular, to downhole systems and methods for the deployment and use of one or more balls for the actuation of downhole tools.
- Without limiting the scope of the present disclosure, its background is described with reference to actuating a downhole tool responsive to tubing pressure applied against a ball disposed in a ball seat, as an example.
- It is well known in the subterranean well drilling and completion art to locate a downhole tool string within a casing, liner or production tubing to perform desired operations. Such a tool string may incorporate a variety of tools including sliding sleeves, circulating subs, packers and the like. Once the tool string is properly positioned downhole, actuation of one or more of the downhole tools in the string may be desired. One method to actuate such downhole tools involves deployment of a ball operable to travel down the tool string and engage a ball seat within the downhole tool or an associated setting tool. Thereafter, tubing pressure may be applied to actuate the downhole tool. For example, in the case of a packer, the ball may engage a seat in a packer setting tool. The fluid pressure is then increased above a certain threshold to actuate the packer setting tool, which in turn sets the packer to engage the casing, liner or production tubing.
- Typically, the ball used to actuate the downhole tool is deployed from the surface. The ball must then be gravity feed or pumped through the pipe string until it reaches the downhole seat. It has been found, however, that although such a method works in many circumstances, there are several drawbacks to this method. For example, deployment of a ball from the surface is a time-consuming and costly process. In addition, deployment of a ball from the surface may result in the ball becoming stuck or lost in the pipe string or otherwise never making it to the downhole seat. Further, to ensure that the ball can be displaced from the surface to the downhole seat, all of the tools and components in the pipe string above the downhole seat must be free from restrictions that would prevent the ball from passing therethrough.
- Accordingly, a need has arisen for an improved system and method for deploying a ball for engagement with a ball seat to enable actuation of a downhole tool. A need has also arisen for such an improved system and method for deploying a ball that does not require gravity feeding or pumping the ball from the surface.
- For a more complete understanding of the features and advantages of the present disclosure, reference is now made to the detailed description of the disclosure along with the accompanying figures in which corresponding numerals in the different figures refer to corresponding parts and in which:
-
FIGS. 1A-1D are schematic illustrations of a downhole ball dropping system according to an embodiment of the present disclosure in various operating configurations; -
FIGS. 2A-2D are schematic illustrations of a downhole ball dropping system according to an embodiment of the present disclosure in various operating configurations; -
FIG. 3 is a process flow diagram of a downhole ball dropping method according to an embodiment of the present disclosure; -
FIGS. 4A-4M are schematic illustrations of various embodiments of actuators that are operable for use in downhole ball dropping systems according to the present disclosure; and -
FIG. 5 is a perspective illustration of a ball release mechanism for use in a downhole ball dropping system according to an embodiment of the present disclosure. - While various system, method and other embodiments are discussed in detail below, it should be appreciated that the present disclosure provides many applicable inventive concepts, which can be embodied in a wide variety of specific contexts. The specific embodiments discussed herein are merely illustrative, and do not delimit the scope of the present disclosure.
- In one aspect, the present disclosure is directed to a downhole ball dropping system that is operable to be positioned in a well. The system includes a tool string having a flow path. First and second ball dropper assemblies are interconnected in the tool string. The first ball dropper assembly releasably retains a first ball and the second ball dropper assembly releasably retains a second ball. A sensor is operable to detect deployment of the first ball and is operable to generate a signal to prevent release of the second ball from the second ball dropper assembly.
- In one embodiment, the second ball dropper assembly may be positioned downhole of the first ball dropper assembly. In another embodiment, the second ball dropper assembly may be circumferentially positioned relative to the first ball dropper assembly. In some embodiments, the sensor may be operable to detect the first ball passing through the flow path after release thereof by the first ball dropper assembly. For example, the first ball may be a magnetic device and the sensor may detect a change in a magnetic field. Alternatively, the first ball may include an RFID tag and the sensor may be an RFID reader. In certain embodiments, the sensor may be operable to detect release of the first ball from first ball dropper assembly.
- In another aspect, the present disclosure is directed to a downhole ball dropping method. The method includes positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path, a first ball dropper assembly interconnected in the tool string and releasably retaining a first ball and a second ball dropper assembly interconnected in the tool string and releasably retaining a second ball; sending a deployment signal to the first ball dropper assembly to release the first ball; detecting deployment of the first ball with a downhole sensor; and generating a deactivation signal from the downhole sensor to prevent release of the second ball from the second ball dropper assembly.
- The method may also include sending a deployment signal selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof; detecting the first ball passing through the flow path after release thereof by the first ball dropper assembly; detecting a change in a magnetic field; detecting an RFID tag; detecting release of the first ball from the first ball dropper assembly; and/or sending a deployment signal from the downhole sensor to at least one of a surface controller and a downhole component.
- In a further aspect, the present disclosure is directed to a downhole ball dropping system that is operable to be positioned in a well. The system includes a tool string having a flow path. A first ball dropper assembly is interconnected in the tool string. The first ball dropper assembly releasably retains a first ball. A first actuation assembly is operably associated with the first ball dropper assembly. The first actuation assembly is operated responsive to a deployment signal of a first type. A second ball dropper assembly is interconnected in the tool string. The second ball dropper assembly releasably retains a second ball. A second actuation assembly is operably associated with the second ball dropper assembly. The second actuation assembly is operated responsive to a deployment signal of a second type, wherein, the deployment signal of the second type is different from the deployment signal of the first type, thereby providing independent and redundant ball deployment capability.
- In one embodiment, the second ball dropper assembly may be positioned downhole of the first ball dropper assembly. In another embodiment, the second ball dropper assembly may be circumferentially positioned relative to the first ball dropper assembly. In some embodiments, the deployment signal of the first type and the deployment signal of the second type may each be selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof.
- In yet another aspect, the present disclosure is directed to a downhole ball dropping method. The method includes positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path, a first ball dropper assembly interconnected in the tool string and releasably retaining a first ball and a second ball dropper assembly interconnected in the tool string and releasably retaining a second ball; sending a deployment signal of a first type to the first ball dropper assembly to release the first ball; determining deployment of the first ball failed with a downhole sensor; and sending a deployment signal of a second type to the second ball dropper assembly to release the second ball, wherein, the deployment signal of the second type is different from the deployment signal of the first type, thereby providing independent and redundant ball deployment capability.
- The method may also include sending a deployment signal selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof; detecting the first ball has not passing through the flow path downhole of the first ball dropper assembly; detecting no a change in a magnetic field; detecting no RFID tag; detecting a failure to release the first ball from the first ball dropper assembly; and/or sending a deployment failure signal from the downhole sensor to at least one of a surface controller and a downhole component.
- In an additional aspect, the present disclosure is directed to a downhole ball dropping method. The method includes positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path and a ball dropper assembly interconnected in the tool string that releasably retains a ball; sending a deployment signal to the ball dropper assembly to release the ball; shifting a piston of a release assembly in the ball dropper assembly; pushing the ball out of the ball dropper assembly through a port with the release assembly; sensing operation of the release assembly and closing the port.
- In another aspect, the present disclosure is directed to a downhole ball dropping system that is operable to be positioned in a well. The system includes a tool string having a flow path. A ball dropper assembly is interconnected in the tool string. The ball dropper assembly releasably retains a ball. An actuation assembly is operably associated with the ball dropper assembly. The actuation assembly is operated responsive to a deployment signal. A release assembly including a piston is disposed within the ball dropper assembly. A sensor is operably associated with the ball dropper assembly. Responsive to the deployment signal, the actuation assembly triggers operation of the release assembly, the release assembly pushes the ball into the flow path through a port of the ball dropper assembly, the sensor senses operation of the release assembly and the port of the ball dropper assembly is closed.
- In a further aspect, the present disclosure is directed to a downhole ball dropping method. The method includes positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path and a ball dropper assembly interconnected in the tool string and releasably retaining a ball; sending a deployment signal to the ball dropper assembly to release the ball; determining whether the ball deployed from the ball dropper assembly with a downhole sensor; and sending a signal from the downhole sensor to at least one of a surface controller and a downhole component indicating whether the ball deployed.
- The method may also include sending a deployment signal selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof; detecting whether the ball has passed through the flow path downhole of the ball dropper assembly; determining whether there is a change in a magnetic field; determining whether an RFID tag is detected; and/or detecting whether the ball was released from the ball dropper assembly.
- Referring now to
FIGS. 1A-1D , a tool string is being positioned in an interval of a wellbore that is generally designated 10.Tool string 12 is being run inwellbore 10 on a conveyance such as a string of jointed tubing, a string of drill pipe, a coiled tubing string or the like.Wellbore 10 extends through the various earthstrata including formation 14. Acasing 16 is positioned withinwellbore 10 and may be secured therein by cement.Casing 16 includes a plurality ofperforations 18. In the illustrated embodiment,tool string 12 has been stabbed into asump packer 20.Tool string 12 has a centralfluid flow path 22 indicated in phantom lines. In the illustrated embodiment,tool string 12 includes a sandcontrol screen assembly 24, aball seat assembly 26 including aball seat 28 indicated in phantom lines, acrossover assembly 30, apacker assembly 32, a settingassembly 34 including aball seat 36 indicated in phantom lines, aball dropper assembly 38 including aball 40, anactuator 42 and asensor assembly 44, and aball dropper assembly 46 including aball 48, anactuator 50 and asensor assembly 52. - Even though
FIG. 1 depicts the tool string of the present disclosure as having a particular arrangement of tools, it should be understood by those skill in the art that tool strings having other arrangements of a greater number or lesser number of tools as well as tool strings having different tools requiring ball activation or ball interaction may alternatively be used. Also, even thoughFIG. 1 depicts the tool string of the present disclosure in a vertical wellbore, it should be understood by those skilled in the art that the tool string of the present disclosure is equally well suited for use in wellbores having other directional configurations including horizontal wellbores, deviated wellbores, slanted wells, lateral wells and the like. In such wells, in addition to or as an alternative to gravity feeding, the balls may be moved within the central fluid flow path by a moving fluid. Accordingly, it should be understood by those skilled in the art that the use of directional terms such as above, below, upper, lower, upward, downward, uphole, downhole and the like are used in relation to the illustrative embodiments as they are depicted in the figures, the upward direction being toward the top of the corresponding figure and the downward direction being toward the bottom of the corresponding figure, the uphole direction being toward the surface of the well and the downhole direction being toward the toe of the well. Further, even though the present description has referred to ball dropper assemblies, balls and ball seats, it is to be understood by those skilled in the art that the term “ball” as used herein will be inclusive of other flowable objects suitable for actuating downhole tools, which may or may not be spherical including, but not limited to, darts and plugs. In addition, the balls used in the systems may be made from a single material such as metal or may be formed from multiple materials such as a rubber exterior with a plastic or metal core. Alternatively or additionally, the balls may be formed from a material that dissolves over time including balls having nanosized elements therein. - Referring specifically to
FIG. 1B , therein is depicted a ball dropping operation of the present disclosure. It should be noted thatball 48 may be used to perform a variety of functions in the well such as plug the tubing to allow pressure build up to actuate a piston setting tool to set a packer, plug the tubing to allow tubing pressure build up to set a hydraulic packer or otherwise actuate a tool, plug the tubing to change a flow path therethrough, for example, to direct proppant flow out into the annulus between the casing and completion hardware, change or reconfigure the flow path of the service tool for a particular operation such as an acid treatment as well as other functions known to those skilled in the art. As illustrated,ball 48 has been deployed fromball dropper assembly 46 intowellbore 10 andball seat 36. As discussed in greater detail below,ball 48 is released fromball dropper assembly 46 responsive to operation ofactuator 50.Actuator 50 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof. More specifically, oncetool string 10 has stabbed intosump packer 20 and it is desired to setpacker assembly 32, the deployment signal is sent to actuator 50 ofball dropper assembly 46. The deployment signal causes actuation ofactuator 50, which in turn causes release ofball 48 intoflow path 22. Gravity, fluid flow or a combination thereof, then causesball 48 to travel downhole and engageball seat 36 of settingassembly 34. Onceball 48 is positioned inball seat 36, fluid pressure acting onball 48 may be used to setpacker assembly 32. - As best seen in
FIG. 1C , oncepacker assembly 32 has been set, additional pressure withinflow path 22 may be used to causeball 48 to pass throughball seat 36 and travel toball seat 28 inball seat assembly 26. In this position, a gravel pack operation may be performed to gravel pack the production interval associated withsand control screen 24 andperforations 18 through cross overassembly 30. Thereafter, additional pressure withinflow path 22 may be used to causeball 48 to pass throughball seat 28 or return flow may be used to retrieveball 48 to the surface or other secure location. - During the process of ball activation of downhole tools, it is important to know whether a ball has been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. For example,
sensor 52 ofball dropper assembly 46 is operable to determine whetherball dropper assembly 46 has releasedball 48 intoflow path 22.Sensor 52 may be a mechanical sensor, an electrical sensor, an optical sensor, a magnetic sensor or the like that is capable of identifying whetherball 48 is located withinball dropper assembly 46, whetherball 48 has passed through a particular location ofball dropper assembly 46 or both. Regardless of the sensing means, ifsensor 52 determines thatball 48 has been released intoflow path 22,sensor 52 is operable to provide a signal that indicatesball 48 has been released intoflow path 22. Depending upon the configuration oftool string 12, this signal may be sent to a surface controller via a wellbore telemetry system or, as illustrated, the signal may be sent directly toball dropper assembly 38 via a wireddownhole communication network 54. Alternatively, the signal may be sent fromsensor 52 toball dropper assembly 38 via a wireless downhole communication system such as via acoustic communication. - As illustrated,
sensor 52 andactuator 50 ofball dropper assembly 46 andsensor 44 andactuator 42 ofball dropper assembly 38 are nodes in wireddownhole communication network 54. Preferably, thesignal indicating ball 48 has been released intoflow path 22 is received bysensor 44 and/oractuator 42 ofball dropper assembly 38. Either or both ofsensor 44 andactuator 42 may include a downhole processor operably to interpret the signal and cause deactivation ofball dropper assembly 38 such thatball 40 will not be released intoflow path 22. In this embodiment, the signal fromsensor 52 indicatingball 48 has been released intoflow path 22 may be referred to as a deactivation signal operable to prevent release a redundant ball; namelyball 40, intoflow path 22. In this manner, proper deployment ofball 48 intoflow path 22 prevents a subsequent unwanted deployment ofball 40 intoflow path 22. - Alternatively or additionally,
sensor 44 ofball dropper assembly 38 may be operable to determine whetherball 48 ofball dropper assembly 46 has enteredflow path 22 and traveledpast sensor 44.Sensor 44 may be a mechanical sensor, an electrical sensor, an optical sensor, a magnetic sensor or the like that is capable of identifying the passing ofball 48 inflow path 22proximate sensor 44. - In one embodiment,
ball 48 may be a magnetic device that includes one or more permanent magnets disposed within or on the surface ofball 48. In this embodiment,sensor 44 may be a giant magneto-resistive (GMR) sensor, a Hall-effect sensor, conductive coils or the like. Permanent magnets can be combined withsensor 44 in order to create a magnetic field that is disturbed byball 48. A change in the magnetic field can be detected bysensor 44 as an indication of the presence or in this case the passage ofball 48. -
Sensor 44 may include electronic circuitry which determines whether the sensor has detected a particular predetermined magnetic field, or pattern or combination of magnetic fields, or other magnetic properties ofball 48. For example, the electronic circuitry could have the predetermined magnetic field(s) or other magnetic properties programmed into non-volatile memory for comparison to magnetic fields/properties detected bysensor 44. The electronic circuitry could be supplied with electrical power via an on-board battery, a downhole generator, or any other electrical power source. - In one example, the electronic circuitry could include a capacitor, wherein an electrical resonance behavior between the capacitance of the capacitor and
sensor 44 changes, depending on whetherball 48 is present. In another example, the electronic circuitry could include an adaptive magnetic field that adjusts to a baseline magnetic field of the surrounding environment such as the formation, the surrounding metallic structures or the like. The electronic circuitry could determine whether the measured magnetic fields exceed the adaptive magnetic field level. In a further example,sensor 44 could comprise an inductive sensor, which can detect the presence of a metallic device by, for example, detecting a change in a magnetic field. In this case,ball 48 need not contain a magnetic element or elements, however,ball 48 can still be considered a magnetic device, in the sense that it conducts a magnetic field and produces changes in a magnetic field, which can be detected bysensor 44. - In another embodiment,
ball 48 may contain an electrical circuit such as, but not limited to, a passive or active radio frequency identification (RFID) tag. In the case ofball 48 containing a passive RFID tag,sensor 44 may include a transmitter operable to transmit an alternating current electromagnetic signal intoflow path 22. Asball 48passes sensor 44, the electrical circuit ofball 44 generates an electromagnetic signal responsive to the alternating current electromagnetic signal. A receiver ofsensor 44 is operable to receive the responsive signal from the electrical circuit. The passive tag circuits have no internal power source, such as a battery. They contain an electromagnetic or electronic coil that can be excited by a particular frequency of electromagnetic energy transmitted from the transmitter ofsensor 44. The electromagnetic energy transmitted from the transmitter to the coil momentarily excites the coil causing the electrical circuit to transmit the contents of its buffer, such as some stored value unique to that particular tag. The transmitted information is then detected by the receiver ofsensor 44. - In the case of
ball 48 containing an active RFID tag, the electrical circuit carried byball 48 generates and transmits an electromagnetic signal. In this case,sensor 44 requires only an RFID reader or receiver operable to receive the electromagnetic signal from the electrical circuit. The active tag circuits contain an internal power source, typically a long life battery. The active tag can have read and write capability, allowing its internal operating program and other information to be remotely updated or changed as required. The active tag's memory can store, for example, several kilobytes information for future recall such as serial numbers, lot numbers, build dates, expiration dates and the like. Additionally, an active tag can be designed to transmit without initiation or interrogation by a transmitter. In this manner, the active tag, under its own power and circuit design or programmed control can self-generate an identifying electromagnetic signal that is detected by the receiver ofsensor 44. - Regardless of the sensing means, if
sensor 44 determines thatball 48 has traveled pastball dropper assembly 38,sensor 44 is operable to provide a deactivation signal such thatball 40 will not be released intoflow path 22. In this manner, proper deployment ofball 48 intoflow path 22 prevents a subsequent unwanted deployment ofball 40 intoflow path 22. - During the process of ball activation of downhole tools, it is important to know whether a ball has not been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. As described above,
sensor 52 and/orsensor 44 are operable to determine whetherball 48 has been deployed fromball dropper assembly 46 intoflow path 22. In the event that the active sensor or sensors determine thatball 48 has not been deployed fromball dropper assembly 46 intoflow path 22, the present disclosure includes a second and redundant ball; namelyball 40, inball dropper assembly 38 that is operable for use in actuating downhole tools such aspacker assembly 32 and cross overassembly 30. In this case,ball 40 is released fromball dropper assembly 38 responsive to operation ofactuator 42.Actuator 42 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof. Preferably,actuator 42 and the required actuation signal foractuator 42 are different fromactuator 50 and the required actuation signal foractuator 50. This is preferred as the cause of the failure of ball deployment fromball dropper assembly 46 may also cause a failure inball dropper assembly 38 if the same type of actuator and same type of actuation signal are used. - As illustrated in
FIG. 1D , if it is determine thatball 48 has not been deployed fromball dropper assembly 46 intoflow path 22 bysensor 52 and/orsensor 44, thenball dropper assembly 38 is sent a deployment signal andball 40 is deployed fromball dropper assembly 38 intoflow path 22. Gravity, fluid flow or a combination thereof, then causesball 40 to travel downhole and engageball seat 36 of settingassembly 34. Onceball 40 is positioned inball seat 36, fluid pressure acting onball 40 may be used to setpacker assembly 32. Thereafter, additional pressure withinflow path 22 may be used to causeball 40 to pass throughball seat 36 and travel toball seat 28 inball seat assembly 26. In this position, a gravel pack operation may be performed to gravel pack the production interval associated withsand control screen 24 andperforations 18 through cross overassembly 30. Thereafter, additional pressure withinflow path 22 may be used to causeball 40 to pass throughball seat 28 or return flow may be used to retrieveball 40 to the surface or other secure location. It is noted thattool string 12 could have one or more additional and redundant ball dropper assemblies that could be used to deploy a redundant ball intoflow path 22 in a manner similar to that ofball 40. - Referring next
FIGS. 2A-2D , a tool string is being positioned in an interval of a wellbore that is generally designated 110.Tool string 112 is being run inwellbore 110 on a conveyance such as a string of jointed tubing, a string of drill pipe, a coiled tubing string or the like.Wellbore 110 extends through the various earthstrata including formation 114. Acasing 116 is positioned withinwellbore 110 and may be secured therein by cement. Casing 116 includes a plurality ofperforations 118. In the illustrated embodiment,tool string 112 has been stabbed into asump packer 120.Tool string 112 has a centralfluid flow path 122 indicated in phantom lines. In the illustrated embodiment,tool string 112 includes a sandcontrol screen assembly 124, aball seat assembly 126 including aball seat 128 indicated in phantom lines, acrossover assembly 130, apacker assembly 132, a settingassembly 134 including aball seat 136 indicated in phantom lines, aball dropper assembly 138 including twoballs actuators sensor assemblies ball dropper assembly 146 including twoballs actuators sensor assemblies - Referring specifically to
FIG. 2B , therein is depicted a ball dropping operation of the present disclosure. As illustrated,ball 140 fromball dropper assembly 138 has been deployed inwellbore 110 toball seat 136. As discussed in greater detail below,ball 140 is released fromball dropper assembly 138 responsive to operation ofactuator 142.Actuator 142 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof More specifically, oncetool string 110 has stabbed intosump packer 120 and it is desired to setpacker assembly 132, the deployment signal is sent to actuator 142 ofball dropper assembly 138. The deployment signal causes actuation ofactuator 142, which in turn causes release ofball 140 intoflow path 122. Gravity, fluid flow or a combination thereof, then causesball 140 to travel downhole and engageball seat 136 of settingassembly 134. Onceball 140 is positioned inball seat 136, fluid pressure acting onball 140 may be used to setpacker assembly 132. - During the process of ball activation of downhole tools, it is important to know whether a ball has been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. For example,
sensor 144 ofball dropper assembly 138 is operable to determine whetherball dropper assembly 138 has releasedball 140 intoflow path 122.Sensor 144 may be a mechanical sensor, an electrical sensor, an optical sensor, a magnetic sensor or the like that is capable of identifying whetherball 140 is located withinball dropper assembly 138, whetherball 140 has passed through a particular location ofball dropper assembly 138, whetherball 140 has passed through a particular location inflow path 122 or combinations thereof Regardless of the sensing means, ifsensor 144 determines thatball 140 has been released intoflow path 122,sensor 144 is operable to provide a signal that indicatesball 140 has been released intoflow path 122. Depending upon the configuration oftool string 112, this signal may be sent to the surface, sent to another downhole tool or, as illustrated, the signal can be processed byball dropper assembly 138 to deactivate the portion ofball dropper assembly 138 responsible for release ofball 141 intoflow path 122. In this manner, proper deployment ofball 140 intoflow path 122 prevents a subsequent unwanted deployment ofball 141 intoflow path 122. - During the process of ball activation of downhole tools, it is important to know whether a ball has not been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. As described above,
sensor 144 is operable to determine whetherball 140 has been deployed fromball dropper assembly 138 intoflow path 122. In the event thatsensor 144 determines thatball 140 has not been deployed fromball dropper assembly 138 intoflow path 122, the present disclosure includes a second and redundant ball; namelyball 141 inball dropper assembly 138 that is operable for use in actuating downhole tools such aspacker assembly 132. In this case,ball 141 is released fromball dropper assembly 138 responsive to operation ofactuator 143.Actuator 143 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof. Preferably,actuator 143 and the required actuation signal foractuator 143 are different fromactuator 142 and the required actuation signal foractuator 142. This is preferred as the cause of the failure of deployment ofball 140 may also cause a failure of deployment ofball 141 if the same type of actuator and same type of actuation signal are used. - As illustrated in
FIG. 2C , if it is determine thatball 140 has not been deployed fromball dropper assembly 138 intoflow path 122 bysensor 144, thenball dropper assembly 138 is sent a deployment signal andball 141 is deployed fromball dropper assembly 138 intoflow path 122. Gravity, fluid flow or a combination thereof, then causesball 141 to travel downhole and engageball seat 136 of settingassembly 134. Onceball 141 is positioned inball seat 136, fluid pressure acting onball 141 may be used to setpacker assembly 132. It is noted thatball dropper assembly 138 could have one or more additional and redundant balls which could be deployed intoflow path 122 in a manner similar to that ofball 141. In addition, it is noted thattool string 112 could have one or more additional and redundant ball dropper assemblies that could be used to deploy a redundant ball intoflow path 122 in a manner similar to that ofball 141. Even thoughball dropper assembly 138 has been referred to as a single ball dropper assembly,ball dropper assembly 138 could alternatively be viewed as including two ball dropper assemblies, the first ball dropper assembly operable to retain andrelease ball 140 and the second ball dropper assembly operable to retain andrelease ball 141. - Whether by
ball 140 orball 141, oncepacker assembly 132 has been set, additional pressure withinflow path 122 may be used to causeball 140 orball 141 to pass throughball seat 136 as well asball seat 128 inball seat assembly 126, which requires a larger ball thanball 140 orball 141, in the illustrated embodiment. Alternatively, return flow may be used to retrieveball 140 orball 141 to the surface or other secure location. Thereafter, as best seen inFIG. 2D ,ball 148 may be deployed fromball dropper assembly 146 toball seat 128.Ball 148 is released fromball dropper assembly 146 responsive to operation ofactuator 150.Actuator 150 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof. The deployment signal causes actuation ofactuator 150, which in turn causes release ofball 148 intoflow path 122. Gravity, fluid flow or a combination thereof, then causesball 148 to travel downhole and engageball seat 128 ofball seat assembly 126. In this position, a gravel pack operation may be performed to gravel pack the production interval associated withsand control screen 124 andperforations 118 through cross overassembly 130. Thereafter, additional pressure withinflow path 122 may be used to causeball 148 to pass throughball seat 128 or return flow may be used to retrieveball 148 to the surface or other secure location. - During the process of ball activation of downhole tools, it is important to know whether a ball has been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. For example,
sensor 152 ofball dropper assembly 146 is operable to determine whetherball dropper assembly 146 has releasedball 148 intoflow path 122.Sensor 152 may be a mechanical sensor, an electrical sensor, an optical sensor, a magnetic sensor or the like that is capable of identifying whetherball 148 is located withinball dropper assembly 146, whetherball 148 has passed through a particular location ofball dropper assembly 146, whetherball 148 has passed through a particular location inflow path 122 or combinations thereof. Regardless of the sensing means, ifsensor 152 determines thatball 148 has been released intoflow path 122,sensor 152 is operable to provide a signal that indicatesball 148 has been released intoflow path 122. Depending upon the configuration oftool string 112, this signal may be sent to the surface, sent to another downhole tool or, as illustrated, the signal can be processed byball dropper assembly 146 to deactivate the portion ofball dropper assembly 146 responsible for release ofball 149 intoflow path 122. In this manner, proper deployment ofball 148 intoflow path 122 prevents a subsequent unwanted deployment ofball 149 intoflow path 122. - During the process of ball activation of downhole tools, it is important to know whether a ball has not been deployed into the flow path of the tool string. In the present disclosure, sensors and systems are incorporated into the tool string to accomplish this operation. As described above,
sensor 152 is operable to determine whetherball 148 has been deployed fromball dropper assembly 146 intoflow path 122. In the event thatsensor 152 determines thatball 148 has not been deployed fromball dropper assembly 146 intoflow path 122, the present disclosure includes a second and redundant ball; namelyball 149 inball dropper assembly 146 that is operable for use in actuating downhole tools such as cross overassembly 130. In this case,ball 149 is released fromball dropper assembly 146 responsive to operation ofactuator 151.Actuator 151 may be actuated responsive to a deployment signal sent from the surface or generated downhole such as a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal or combinations thereof. Preferably,actuator 151 and the required actuation signal foractuator 151 are different fromactuator 150 and the required actuation signal foractuator 150. This is preferred as the cause of the failure of deployment ofball 148 may also cause a failure of deployment ofball 149 if the same type of actuator and same type of actuation signal are used. - If it is determine that
ball 148 has not been deployed fromball dropper assembly 146 intoflow path 122 bysensor 152, thenball dropper assembly 146 is sent a deployment signal andball 149 is deployed fromball dropper assembly 146 into flow path 122 (not pictured). Gravity, fluid flow or a combination thereof, then causesball 149 to travel downhole and engageball seat 128 ofball seat assembly 126. In this position, a gravel pack operation may be performed to gravel pack the production interval associated withsand control screen 124 andperforations 118 through cross overassembly 130. Thereafter, additional pressure withinflow path 122 may be used to causeball 149 to pass throughball seat 128 or return flow may be used to retrieveball 149 to the surface or other secure location. It is noted thatball dropper assembly 146 could have one or more additional and redundant balls which could be deployed intoflow path 122 in a manner similar to that ofball 149. In addition, it is noted thattool string 112 could have one or more additional and redundant ball dropper assemblies that could be used to deploy a redundant ball intoflow path 122 in a manner similar to that ofball 149. - Referring next to
FIG. 3 , a process flow diagram generally designated 200, depicts a method for actuating a downhole tool using a downhole ball dropping system according to an embodiment of the present disclosure. The process begins by positioning the downhole ball dropping system in a well atstep 202. Once properly positioned in the well and it is desired to operate a downhole tool that requires ball interaction, a deployment signal is sent to actuate an actuator to cause release of a ball by a ball dropper assembly into the flow path atstep 204. The deployment signal may be a sent from a surface controller or may be generated downhole as described above. One or more sensors then determine whether a ball has been properly deployed indecision 206. If the sensor determines that a ball has been properly deployed, the sensor generates one or more deactivation signals to prevent release of any redundant balls from a ball dropper assembly into the flow path instep 208. The deactivation signals may be sent directly to the appropriate ball dropper assembly or assemblies and may alternatively or additionally be sent to the surface controller. If the deactivation signal is first sent to the surface controller, the well operator may acknowledge the received signal and then send one or more deactivation signals to the appropriate ball dropper assembly or assemblies as required. The process then progresses to actuating the downhole tool with the deployed ball instep 210. If indecision 206 the sensor determines that a ball has not been properly deployed, the sensor generates a signal indicative of this failure, which is preferably sent to the surface controller where it is determined whether a redundant ball is available in a ball dropper assembly indecision 212. If the failure signal is sent to the surface controller, the well operator may acknowledge the received signal before moving to the next step. If no redundant ball is available, the process ends. If a redundant ball is available, a signal is sent, for example from the surface controller, to actuate an actuator to cause release of a redundant ball from a ball dropper assembly into the flow path atstep 214. The process then returns todecision 206 to determine whether a ball has been properly deployed and a single indicating whether the ball has been deployed may be sent to the surface controller. The process can continue until either, a redundant ball is properly deployed, a deactivation signal is sent and the downhole tool is actuated or no redundant balls are available. - Referring next to
FIGS. 4A-4M , therein are depicted schematic illustrations of various actuators that are operable for use in the downhole ball dropper assemblies of the present disclosure. InFIG. 4A ,actuator 300 includes anouter housing 302 and aninner sleeve 304 having aball release opening 306.Outer housing 302 andinner sleeve 304 are initially secured together with a shearable member depicted asshear screw 308Inner sleeve 304 is threadably coupled to alower connector 310. In the illustrated embodiment, acylindrical region 312 is formed betweenouter housing 302 andinner sleeve 304. Aball ramp 314 is sealably positioned incylindrical region 312 and is preferably secured toouter housing 302.Ball ramp 314 includes afluid passageway 316 having ametering valve circuit 318 positioned therein. Afluid chamber 320 is defined between the lower end ofball ramp 314,outer housing 302 andinner sleeve 304. A viscous fluid such as oil is contained withinfluid chamber 320. In addition, areturn spring 322 is positioned withinfluid chamber 320. Amandrel 324 is securably coupled toouter housing 302.Mandel 324 includes a spring loadedball support member 326. Aball 328 is initially coupled toball support 326 by a magnetic coupling, a shearable member or the like. One ormore sensors 330 are located in proximity toball 328 and are operable to provide a signal that indicatesball 328 has or has not been released into the flow path as described above. - In operation,
actuator 300releases ball 328 responsive to a mechanical deployment signal. Specifically, when the toolstring including actuator 300 is positioned in the well and it is desired to deployball 328 into the flow path of the tool string, weight is applied onmandrel 324. When sufficient shear force is generated betweenouter housing 302 andinner sleeve 304,shear screw 308 is broken. Thereafter, theouter housing 302,ball ramp 314 andmandrel 324 are shiftable relative toinner sleeve 304. The downward force onmandrel 304 now compressesspring 322 and is counteracted by the fluid moving throughmetering valve circuit 318 to require a predetermined amount of time for this operation. Asouter housing 302,ball ramp 314 andmandrel 324 move downwardly relative toinner sleeve 304,ball 328 becomes aligned with ball release opening 306 ofinner sleeve 304 andball 328 is released fromball support member 326, through ball release opening 306 and into the flow path of the tool string. After deployment ofball 328, release of weight onmandrel 324 allowsspring 322 to returnouter housing 302,ball ramp 314 andmandrel 324 substantially to their run in positions. - In
FIG. 4B ,actuator 330 includes anouter housing 332 and aninner sleeve 334 having aball release opening 336.Outer housing 332 includes afluid passageway 338 that is in fluid communication with the annulus whenactuator 300 is positioned in the well.Outer housing 302 is threadably coupled to alower connector 340. In the illustrated embodiment, acylindrical region 342 is formed betweenouter housing 332 andinner sleeve 334. Aball ramp 344 is positioned in a lower portion ofcylindrical region 342 and aball release assembly 346 is positioned in an upper portion ofcylindrical region 342.Ball release assembly 346 has acylindrical chamber 348 that is in fluid communication withfluid passageway 338. Apiston 350 is sealably disposed withincylindrical chamber 348 and is initially secured therein with a shearable member depicted asshear screw 352. Belowpiston 350,cylindrical chamber 348 contains a viscous fluid such asoil 354. A fluid flow control element depicted asorifice 356 is positioned betweenoil 354 and apiston 358. The lower end ofpiston 358 is proximate to or in contact withball 360, which is held in place by aresilient ball holder 362. One ormore sensors 364 are located in proximity toball 360 and are operable to provide a signal that indicatesball 360 has or has not been released into the flow path as described above. - In operation,
actuator 330releases ball 360 responsive to a pressure deployment signal. Specifically, when the toolstring including actuator 330 is positioned in the well and it is desired to deployball 360 into the flow path of the tool string, annulus pressure is increased to apply a downward force onpiston 350. When sufficient shear force is generated betweenpiston 350 andball release assembly 346,shear screw 352 is broken. Thereafter, thepiston 350 is shiftable relative to ball releaseassembly 346. The downward force onpiston 350 is counteracted byfluid 354 moving throughorifice 356 to require a predetermined amount of time for this operation. Aspiston 350 moves downwardly, fluid 354 acts onpiston 358, which shiftspiston 358 downwardly pushingball 360 out ofball holder 362.Ball 360 thencontacts ball ramp 344 which is aligned with ball release opening 336 enablingball 360 to enter the flow path of the tool string. It is noted that the pressure deployment signal could alternatively be generated by increasing the tubing pressure by portingcylindrical chamber 348 to the tubing side. - In
FIG. 4C ,actuator 400 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404.Cylindrical chamber 430 is in fluid communication with afluid passageway 434 that is ported to the annulus and afluid passageway 436, which is ported to the flow path of the tool string. Apiston 438 is sealably disposed withincylindrical chamber 430 and is initially secured therein with a shearable member depicted asshear screw 440. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. For example, whenball release assembly 410 is operated such thatlower ramp element 422 ofplunger member 420 slides intoslot 418 ofball ramp 412, this is an indication thatball 428 has been expelled into the tubing. The one ormore sensors 442 may determine that the two parts have slide together, for example, by opening or closing an electronic circuit, by cutting an electrical wire or breaking an optical fiber, by actuating a pressure switch, by aligning a magnet with a Hall Sensor or the like. The signal that indicates whetherball 428 has or has not been released into the flow path may be sent to a surface control by a wellbore communication means including, but not limited to, a electric conductor, an optical fiber, acoustic or electromagnetic telemetry or other suitable means.Actuator 400 may also include alock assembly 444 that interacts with alocking feature 446 ofpiston 438 whenpiston 438 is fully extended. - In operation,
actuator 400releases ball 428 responsive to a differential pressure deployment signal. Specifically, when the toolstring including actuator 400 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, tubing pressure is increased to generate a differential pressure between the tubing pressure and the annulus pressure which applies a downward force onpiston 438. When sufficient shear force is generated,shear screw 440 is broken. Thereafter,piston 438 is shiftable relative toouter housing 402 and the downward force onpiston 438 acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 may be fully extended such that lockingfeature 446 interacts withlock assembly 444 preventing retraction ofpiston 438. In this configuration, ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 400 from abrasive fluid flow. - In
FIG. 4D ,actuator 450 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 436, which is ported to the flow path of the tool string. Apiston 438 is sealably disposed withincylindrical chamber 430. Arupture disk 452 is also disposed withincylindrical chamber 430 betweenfluid passageway 436 andpiston 438. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation,
actuator 450releases ball 428 responsive to a pressure deployment signal. Specifically, when the toolstring including actuator 450 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, tubing pressure is increased which acts onrupture disk 452. When the tubing pressure reaches a sufficient absolute pressure,rupture disk 452 will burst. Thereafter, the fluid pressure generates a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 450 from abrasive fluid flow. - In
FIG. 4E ,actuator 460 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 434, which is ported to the annulus. Apiston 438 is sealably disposed withincylindrical chamber 430. Alock assembly 462 is also disposed withincylindrical chamber 430.Lock assembly 462 includes alock ring 464, apiston 466 and aretainer member 468. Initially, movement ofpiston 466 andlock ring 464 is prevented by the secure connection betweenpiston 466 andretainer member 468 depicted as ashear screw 470. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation,
actuator 460releases ball 428 responsive to a pressure deployment signal. Specifically, when the toolstring including actuator 460 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, annulus pressure is increased which acts onpiston 466. When sufficient shear force is generated,shear screw 470 is broken allowingpiston 466 to shift upwardly releasinglock ring 464. Thereafter, the fluid pressure generates a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 460 from abrasive fluid flow. - In
FIG. 4F ,actuator 480 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404.Cylindrical chamber 430 is in fluid communication with afluid passageway 434 that is ported to the annulus and afluid passageway 436, which is ported to the flow path of the tool string. Adual piston assembly 482 is sealably disposed withincylindrical chamber 430.Dual piston assembly 482 includes alower piston 484 that has an outer surface operable to cooperate withratchet keys 486 to allow relative downward movement oflower piston 484 but prevent relative upward movement oflower piston 484.Dual piston assembly 482 also includes anupper piston 488 that has an outer surface operable to cooperate withratchet keys 490 to allow relative upward movement oflower piston 488 but prevent relative downward movement oflower piston 488. A biasing member depicted as a spiralwound compression spring 492 is positioned betweenupper piston 488 and alock ring 494 that is secured withincylindrical chamber 430.Spring 492 acts to separateupper piston 488 fromlower piston 484. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation,
actuator 480releases ball 428 responsive to a pressure deployment signal. Specifically, when the toolstring including actuator 480 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, tubing pressure is increased which actsupper piston 488compressing spring 492. Downward movement ofupper piston 488 downwardly shiftslower piston 484 downwardly viaratchet keys 490. At the same time,lower piston 484 is able to move downwardly relative to ratchetkeys 486. When tubing pressure is released, the biasing force ofspring 492 either alone or in combination with the fluid pressure force of the annular fluid viafluid passageway 434 acts to upwardly shiftupper piston 488 which is able to move upwardly relative to ratchetkeys 490. At the same time, ratchetkeys 486 prevent upward movement oflower piston 484. The tubing pressure is then cycled up and down in a manner similar to that described above to further downwardly shiftlower piston 484 in a stepwise fashion. This process continues aslower piston 484 andinner sleeve 404 move together andspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428, further downward movement ofinner sleeve 404 positions ball release opening 406 behind a lower portion ofouter housing 402 to protect the inside components ofactuator 480 from abrasive fluid flow. - In
FIG. 4G ,actuator 500 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420. -
Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes achamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448. An upper portion ofcylindrical chamber 430 is in fluid communication with afluid passageway 434, which is ported to the annulus. Apiston 438 is sealably disposed withincylindrical chamber 430. A computer controlledlock assembly 502 is also disposed withincylindrical chamber 430. Computer controlledlock assembly 502 may include a self contained power source such as one or more batteries, a processor, memory, instructions and a motor having a retractable arm with alock ring 504 attached thereto. Computer controlledlock assembly 502 may receive external stimuli from one ormore sensors more sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation, depending upon the configuration of computer controlled
lock assembly 502,actuator 500releases ball 428 responsive to one or more of an acoustic deployment signal, a pressure deployment signal, a temperature deployment signal, a displacement deployment signal and a time delay deployment signal or combinations thereof. For example, a pressure deployment signal may be detected bysensor 506,sensor 508 or both. Alternatively or additionally, an acoustic deployment signal or a temperature deployment signal could be detected bysensor 506,sensor 508 or both. As yet another alternative, an accelerometer and timer may work together to generate a deployment signal based uponactuator 500 remaining stationary for a predetermined time period. This deployment signal may be in addition to one of the exterior stimuli, i.e., pressure, temperature, acoustic, discussed above. Regardless of the type or types of deployment signals used, once received, the processor of computer controlledlock assembly 502 verifies the deployment signal then triggers the motor to retract its arm along withlock ring 504 to releasepiston 438. Thereafter, annular fluid pressure viafluid passageway 434 generates a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 500 from abrasive fluid flow. - In
FIG. 4H ,actuator 510 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448. Apiston 438 is sealably disposed withincylindrical chamber 430. Amotor 512 having anextendable shaft 514 is also disposed withincylindrical chamber 430. In the illustrated embodiment,motor 512 receives power and command signals viacommunication cable 516 including one or more electrical conductors and one or more optional optical conductors communicably linked to a surface controller or other downhole controller. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation,
actuator 510releases ball 428 responsive to one or more of an optical and an electrical deployment signal. Specifically, when the toolstring including actuator 510 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, the surface controller sends the deployment signal and provides power to operatemotor 512. In the illustrated embodiment, the motor drives theextendable shaft 514 downward generating a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428, further downward movement ofinner sleeve 404 positions ball release opening 406 behind a lower portion ofouter housing 402 to protect the inside components ofactuator 510 from abrasive fluid flow. - In
FIG. 41 ,actuator 520 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 434, which is ported to the annulus. Apiston 438 is sealably disposed withincylindrical chamber 430. A computer controlledrelease assembly 522 is also disposed withincylindrical chamber 430. Computer controlledrelease assembly 522 may include a self contained power source such as one or more batteries, a processor, memory, instructions and a motor having aretractable arm 524 that is sealable received withincylindrical chamber 430. Computer controlledrelease assembly 502 may receive external stimuli from one ormore sensors 526 such as pressure sensors, temperature sensors, hydrophones or the like. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation, depending upon the configuration of computer controlled
release assembly 522,actuator 520releases ball 428 responsive to one or more of an acoustic deployment signal, a pressure deployment signal, a temperature deployment signal, a displacement deployment signal and a time delay deployment signal or combinations thereof. Regardless of the type or types of deployment signals used, once received, the processor of computer controlledrelease assembly 522 verifies the deployment signal then triggers the motor to retractarm 524 which exposescylindrical chamber 430 to annular pressure generating a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 520 from abrasive fluid flow. - In
FIG. 4J ,actuator 530 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420. -
Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 434, which is ported to the annulus. Apiston 438 is sealably disposed withincylindrical chamber 430. A computer controlledrelease assembly 532 is also disposed withincylindrical chamber 430. Computer controlledrelease assembly 532 may include a self-contained power source such as one or more batteries, a processor, memory and instructions. Computer controlledrelease assembly 532 is operably coupled to a disappearingplug 534 disposed influid passageway 434 viawire 536. Computer controlledrelease assembly 532 may receive external stimuli from one ormore sensors 538 such as pressure sensors, temperature sensors, hydrophones or the like. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation, depending upon the configuration of computer controlled
release assembly 532,actuator 530releases ball 428 responsive to one or more of an acoustic deployment signal, a pressure deployment signal, a temperature deployment signal, a displacement deployment signal and a time delay deployment signal or combinations thereof Regardless of the type or types of deployment signals used, once received, the processor of computer controlledrelease assembly 532 verifies the deployment signal then triggers a current flow to generate heat inwire 536 which melts or otherwise removes plug 534 and exposescylindrical chamber 430 to annular pressure generating a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 530 from abrasive fluid flow. - In
FIG. 4K ,actuator 540 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 436, which is ported to the flow path of the tool string. Apiston 438 is sealably disposed withincylindrical chamber 430. A computer controlledrelease assembly 542 is also disposed withincylindrical chamber 430. Computer controlledrelease assembly 542 may include a self-contained power source such as one or more batteries, a processor, memory and instructions. Computer controlledrelease assembly 542 is operably coupled to a disappearingplug 544 disposed in anorifice 546 viawire 548. Computer controlledrelease assembly 542 may receive external stimuli from one ormore sensors 550 such as pressure sensors, temperature sensors, hydrophones or the like. Also disposed withincylindrical chamber 430 is apiston 552. Aviscous fluid 554, such as oil, is disposed betweenpiston 552 andorifice 546. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation, depending upon the configuration of computer controlled
release assembly 542,actuator 540releases ball 428 responsive to one or more of an acoustic deployment signal, a pressure deployment signal, a temperature deployment signal, a displacement deployment signal and a time delay deployment signal or combinations thereof. Regardless of the type or types of deployment signals used, once received, the processor of computer controlledrelease assembly 542 verifies the deployment signal then triggers a current flow to generate heat inwire 548 which melts or otherwise removesplug 544. Tubing pressure viafluid passageway 436 acts onpiston 552 to movepiston 552 downwardly. The downward force onpiston 552 is counteracted byfluid 554 moving throughorifice 546 to require a predetermined amount of time for this operation. After passing throughorifice 546, fluid 554 acts onpiston 438, which in turn acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 540 from abrasive fluid flow. - In
FIG. 4L ,actuator 560 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404. Apiston 438 is sealably disposed withincylindrical chamber 430. A computer controlledrelease assembly 562 is also disposed withincylindrical chamber 430. Computer controlledrelease assembly 562 may include a self-contained power source such as one or more batteries, a processor, memory and instructions. Computer controlledrelease assembly 562 is operably coupled to afluid pump 564. Afluid passageway 566 extends throughouter housing 402 connecting a lower portion ofcylindrical chamber 430 with an inlet offluid pump 564. A fluid 568 is disposed withincylindrical chamber 430 and is operably to be pumped therein. Computer controlledrelease assembly 562 may receive external stimuli from one ormore sensors 570 such as pressure sensors, temperature sensors, hydrophones or the like. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation, depending upon the configuration of computer controlled
release assembly 562,actuator 560releases ball 428 responsive to one or more of an acoustic deployment signal, a pressure deployment signal, a temperature deployment signal, a displacement deployment signal and a time delay deployment signal or combinations thereof. Regardless of the type or types of deployment signals used, once received, the processor of computer controlledrelease assembly 562 verifies the deployment signal then triggers operation offluid pump 564 which circulates fluid throughcylindrical chamber 430 creating a high pressure regions above and a low pressure region belowpiston 438. This action generates a downward force onpiston 438, which acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428, further downward movement ofinner sleeve 404 positions ball release opening 406 behind a lower portion ofouter housing 402 to protect the inside components ofactuator 560 from abrasive fluid flow. - In
FIG. 4M ,actuator 580 includes anouter housing 402 and aninner sleeve 404 having aball release opening 406. In the illustrated embodiment,inner sleeve 404 is slidably disposed withinouter housing 402. A lowercylindrical chamber 408 is defined betweeninner sleeve 404 andouter housing 402. Aball release assembly 410 is positioned incylindrical chamber 408.Ball release assembly 410 includes aball ramp 412 having a pair oframp members slot 418 therebetween, as best seen inFIG. 5 .Ball release assembly 410 also includes aplunger member 420 having alower ramp element 422 that is operable to enterslot 418 ofball ramp 412.Ball release assembly 410 further includes a biasing member depicted as spiralwound compression spring 424 that is disposed around anupper extension 426 ofplunger member 420. In certain embodiments,plunger member 420 may optionally be secured toouter housing 402 in the run in configuration. Aball 428 is positioned withincylindrical chamber 408 betweenball ramp 412 andplunger member 420.Ball 428 may initially be secured toball ramp 412 and/orplunger member 420 magnetically, shearably or the like.Outer housing 402 includes acylindrical chamber 430 located above an upper surface ofplatform 432 ofinner sleeve 404, the lower portion of which is anatmospheric chamber 448.Cylindrical chamber 430 is in fluid communication with afluid passageway 436, which is ported to the flow path of the tool string. Apiston 438 is sealably disposed withincylindrical chamber 430. Anelectromagnet 582 is also disposed withincylindrical chamber 430.Electromagnet 582 is powered viawire 584, which is coupled to an electrical source located downhole or at the surface.Electromagnet 582 is operable to generate a magnetic field that acts on magneto-rheological fluid 586 to form a barrier withincylindrical chamber 430. Also disposed withincylindrical chamber 430 is apiston 588. One ormore sensors 442 may be located in proximity toball 428 and are operable to provide a signal that indicatesball 428 has or has not been released into the flow path as described above. - In operation,
actuator 580releases ball 428 responsive to an electrical deployment signal. Specifically, when the toolstring including actuator 580 is positioned in the well and it is desired to deployball 428 into the flow path of the tool string, the electric power toelectromagnet 582 is cut off. The magneto-rheological fluid 586 that previously formed a barrier not returns to its liquid state. Tubing pressure viafluid passageway 436 acts onpiston 588 to movepiston 588 downwardly causing fluid 586 to acts onpiston 438 which in turn acts throughinner sleeve 404 to compressspring 424. Now,piston 438 andinner sleeve 404 move together untilspring 424 is fully compressed or a lower surface ofplatform 432 ofinner sleeve 404 contactsupper extension 426 ofplunger member 420. In this position,ball 428 is aligned withball release opening 406. Further downward movement ofpiston 438 andinner sleeve 404 now causesplunger member 420 to shift downwardly relative toball ramp 412. The combination of the downward movement ofpiston 438 andinner sleeve 404 together with the force generated byspring 424 betweenball ramp 412 andplunger member 420cause ball 428 to be expelled through ball release opening 406 and into the flow path of the tool string. After deployment ofball 428,piston 438 preferably remains in its fully extended positioned wherein ball release opening 406 has moved behind a lower portion ofouter housing 402 to protect the inside components ofactuator 580 from abrasive fluid flow. - It should be understood by those skilled in the art that the illustrative embodiments described herein are not intended to be construed in a limiting sense. Various modifications and combinations of the illustrative embodiments as well as other embodiments will be apparent to persons skilled in the art upon reference to this disclosure. It is, therefore, intended that the appended claims encompass any such modifications or embodiments.
Claims (20)
1. A downhole ball dropping system operable to be positioned in a well, the system comprising:
a tool string having a flow path;
a first ball dropper assembly interconnected in the tool string, the first ball dropper assembly releasably retaining a first ball;
a second ball dropper assembly interconnected in the tool string, the second ball dropper assembly releasably retaining a second ball; and
a sensor operable to detect deployment of the first ball and operable to generate a signal to prevent release of the second ball from the second ball dropper assembly.
2. The downhole ball dropping system as recited in claim 1 wherein the second ball dropper assembly is positioned downhole of the first ball dropper assembly.
3. The downhole ball dropping system as recited in claim 1 wherein the second ball dropper assembly is circumferentially positioned relative to the first ball dropper assembly.
4. The downhole ball dropping system as recited in claim 1 wherein the sensor is operable to detect the first ball passing through the flow path after release thereof by the first ball dropper assembly.
5. The downhole ball dropping system as recited in claim 4 wherein the first ball further comprises a magnetic device and wherein the sensor detects a change in a magnetic field.
6. The downhole ball dropping system as recited in claim 4 wherein the first ball further comprises an RFID tag and wherein the sensor further comprises an RFID reader.
7. The downhole ball dropping system as recited in claim 1 wherein the sensor is operable to detect release of the first ball from first ball dropper assembly.
8. A downhole ball dropping method comprising:
positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path, a first ball dropper assembly interconnected in the tool string and releasably retaining a first ball and a second ball dropper assembly interconnected in the tool string and releasably retaining a second ball;
sending a deployment signal to the first ball dropper assembly to release the first ball;
detecting deployment of the first ball with a downhole sensor; and
generating a deactivation signal from the downhole sensor to prevent release of the second ball from the second ball dropper assembly.
9. The downhole ball dropping method as recited in claim 8 wherein sending the deployment signal to the first ball dropper assembly to release the first ball further comprises sending a deployment signal selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof.
10. The downhole ball dropping method as recited in claim 8 wherein detecting deployment of the first ball with the downhole sensor further comprises detecting the first ball passing through the flow path after release thereof by the first ball dropper assembly.
11. The downhole ball dropping method as recited in claim 10 wherein detecting the first ball passing through the flow path after release thereof by the first ball dropper assembly further comprises detecting a change in a magnetic field.
12. The downhole ball dropping method as recited in claim 10 wherein detecting the first ball passing through the flow path after release thereof by the first ball dropper assembly further comprises detecting an RFID tag.
13. The downhole ball dropping method as recited in claim 8 wherein detecting deployment of the first ball with the downhole sensor further comprises detecting release of the first ball from first ball dropper assembly.
14. A downhole ball dropping system operable to be positioned in a well, the system comprising:
a tool string having a flow path;
a first ball dropper assembly interconnected in the tool string, the first ball dropper assembly releasably retaining a first ball;
a first actuation assembly operably associated with the first ball dropper assembly, the first actuation assembly operated responsive to a deployment signal of a first type;
a second ball dropper assembly interconnected in the tool string, the second ball dropper assembly releasably retaining a second ball; and
a second actuation assembly operably associated with the second ball dropper assembly, the second actuation assembly operated responsive to a deployment signal of a second type,
wherein, the deployment signal of the second type is different from the deployment signal of the first type, thereby providing independent and redundant ball deployment capability.
15. The downhole ball dropping system as recited in claim 14 wherein the second ball dropper assembly is positioned downhole of the first ball dropper assembly.
16. The downhole ball dropping system as recited in claim 14 wherein the second ball dropper assembly is circumferentially positioned relative to the first ball dropper assembly.
17. The downhole ball dropping system as recited in claim 14 wherein the deployment signal of the first type and the deployment signal of the second type are each selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof
18. A downhole ball dropping method comprising:
positioning a downhole ball dropping system in a well, the downhole ball dropping system including a tool string having a flow path, a first ball dropper assembly interconnected in the tool string and releasably retaining a first ball and a second ball dropper assembly interconnected in the tool string and releasably retaining a second ball;
sending a deployment signal of a first type to the first ball dropper assembly to release the first ball;
determining deployment of the first ball failed; and
sending a deployment signal of a second type to the second ball dropper assembly to release the second ball,
wherein, the deployment signal of the second type is different from the deployment signal of the first type, thereby providing independent and redundant ball deployment capability.
19. The downhole ball dropping method as recited in claim 18 wherein determining deployment of the first ball failed further comprises determining deployment of the first ball failed with a downhole sensor.
20. The downhole ball dropping method as recited in claim 18 wherein sending the deployment signal of the first type and sending the deployment signal of the second type each further comprises sending a deployment signal selected from the group consisting of a mechanical signal, a pressure signal, an acoustic signal, an optical signal, an electrical signal, a temperature signal, a displacement signal, a time delay signal and combinations thereof
Priority Applications (1)
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US14/446,918 US20150068772A1 (en) | 2013-09-10 | 2014-07-30 | Downhole Ball Dropping Systems and Methods with Redundant Ball Dropping Capability |
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USPCT/US2013/058952 | 2013-09-10 | ||
PCT/US2013/058952 WO2015038095A1 (en) | 2013-09-10 | 2013-09-10 | Downhole ball dropping systems and methods with redundant ball dropping capability |
US14/446,918 US20150068772A1 (en) | 2013-09-10 | 2014-07-30 | Downhole Ball Dropping Systems and Methods with Redundant Ball Dropping Capability |
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US10443338B2 (en) * | 2014-03-10 | 2019-10-15 | Baker Hughes, A Ge Company, Llc | Pressure actuated frack ball releasing tool |
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US9810036B2 (en) * | 2014-03-10 | 2017-11-07 | Baker Hughes | Pressure actuated frack ball releasing tool |
US20180045015A1 (en) * | 2014-03-10 | 2018-02-15 | Baker Hughes, A Ge Company, Llc | Pressure Actuated Frack Ball Releasing Tool |
US9708894B2 (en) | 2014-08-27 | 2017-07-18 | Baker Hughes Incorporated | Inertial occlusion release device |
US9745847B2 (en) | 2014-08-27 | 2017-08-29 | Baker Hughes Incorporated | Conditional occlusion release device |
US10100601B2 (en) | 2014-12-16 | 2018-10-16 | Baker Hughes, A Ge Company, Llc | Downhole assembly having isolation tool and method |
GB2563773A (en) * | 2016-04-29 | 2018-12-26 | Halliburton Energy Services Inc | Restriction system for tracking downhole devices with unique pressure signals |
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US11131183B2 (en) | 2016-04-29 | 2021-09-28 | Halliburton Energy Services, Inc. | Restriction system for tracking downhole devices with unique pressure signals |
US10428623B2 (en) | 2016-11-01 | 2019-10-01 | Baker Hughes, A Ge Company, Llc | Ball dropping system and method |
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US20190284933A1 (en) * | 2018-03-19 | 2019-09-19 | Saudi Arabian Oil Company | Multi-zone well testing |
US10982538B2 (en) * | 2018-03-19 | 2021-04-20 | Saudi Arabian Oil Company | Multi-zone well testing |
US11525941B2 (en) * | 2018-03-28 | 2022-12-13 | Halliburton Energy Services, Inc. | In-situ calibration of borehole gravimeters |
US10934809B2 (en) | 2019-06-06 | 2021-03-02 | Becker Oil Tools LLC | Hydrostatically activated ball-release tool |
US11313201B1 (en) | 2020-10-27 | 2022-04-26 | Halliburton Energy Services, Inc. | Well sealing tool with controlled-volume gland opening |
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