1. Field of the Invention
The present invention relates generally to a downhole device that may be used to divert fluid out of a work string and into the annulus between the work string and the tubing or casing. The downhole device may be located at any point along a work string at which it may be necessary to divert the fluid flow to the annulus. The downhole device may be activated and deactivate inserting a single dart into the work string. The device catches the dart, which blocks the fluid flow through the work string. The increased fluid pressure due to the blocked flow path activates the device, which diverts the fluid flow out of the work string into the annulus. The increased fluid pressure moves a circulating sleeve within the device to align fluid ports allowing fluid flow into the annulus. A locating sleeve with a continuous j-track allows the device to be retained in activated position. The dart is adapted to deform under a predetermined amount of fluid pressure, thus passing the dart past the device and returning fluid flow through the work string. The downhole device may be activated multiple times without removing the downhole device from the wellbore.
2. Description of the Related Art
In the oil and gas industry long tubular work strings are often used in drilling, completion, displacement, and/or work over operations. Often the work string is used to carry fluid down the well to a tool located at the end of the work string. For example, fluid may be circulated down a work string and out of a drill bit located at the end of the work string. Often drilling mud is pumped down the work string and through the drill bit. The drilling mud acts as a lubricant, but also carries the drill cuttings up the annulus around the work string to the surface.
Under certain circumstances it may be desirable to circulate fluid into the annulus surrounding the work string at a particular location. For example, the drilling mud may be entering into a porous well formation instead of properly circulating the drill cuttings to the surface. In this instance, it may be necessary to inject a sealing agent into the formation in an attempt to prevent the future loss of mud into the formation. A number of systems have been disclosed that enable the circulation of fluid to the annulus without having to remove the work string from the well bore.
U.S. Pat. No. 4,889,199 discloses a downhole device that allows annular circulation after dropping a plastic ball into the work string. The work string is broken at the surface and a plastic ball is dropped into the work string. The work string is then reconnected and fluid is pumped into the work string until the ball reaches the downhole device. The downhole device includes a shoulder that is adapted to catch the ball within the work string. Once seated on the shoulder the ball blocks the fluid flow through the work string and continual pumping of fluid causes fluid pressure to build above the seated ball. The device includes a ported sleeve that is adapted to move within the device. The sleeve is biased to an initial position by a spring. Once the force on the ball due to the fluid pressure is greater than the spring force, the ported sleeve moves within the device such that ports in the sleeve align with exterior ports in device allowing fluid to be circulated out of the work string into the annulus. When the sleeve is in its initial position the exterior ports in the work string are sealed preventing fluid flow to the annulus.
To remove the ball from the shoulder in the device, a number of smaller steel balls must be dropped into the work string, which again requires that the work string be disconnected at the surface. The number of steel balls inserted into the work string must be equal to the number of annular ports in the sleeve. The work string is then reconnected and fluid is pumped until the steel balls reach the downhole device. The steel balls are sized such that they fit within the sleeve ports blocking the fluid flow to the annulus. With the fluid flow to the annulus blocked by the steel balls and the fluid flow through the work string prevented by the plastic ball, the fluid pumped into the work string causes the fluid pressure within the work string to increase above the device until the plastic ball is deformed and pushed past the shoulder. The deformed plastic ball falls into a housing located at the bottom of the device. This allows fluid to once again flow through the work string past the device and the steel balls, which are sized smaller than the plastic ball, pass the shoulder and also are captured in the housing below the device. The sleeve is returned to its initial position due to the biasing spring until the next plastic ball is inserted into the work string.
While the disclosed device does provide for annular flow out of the work string it requires that the work string be broken each time fluid flow is diverted out of the work string and each time fluid flow is returned. This process causes increases in well services costs as well as providing multiple opportunities for operator error. Further, the disclosed device requires the use of multiple balls on each cycle. These balls accumulate below the device in the housing or alternatively are dropped into the well. The large number of balls requires a rather large housing or alternatively requires that the device be brought to the surface frequently to remove the passed balls.
The use of a plastic ball may make it difficult for operators or well service providers to accurately predict the amount of fluid pressure required to pass the ball past the shoulder within the device. The temperature within the well may cause the plastic ball to be a different size than at surface temperatures. The temperature within the well may also cause the dimensions of the shoulder to change, but because the shoulder is not comprised of plastic the change in shape may not correlate with the changes reflected in the ball. This may further make it difficult to predict the fluid pressure necessary to pass the plastic ball past the shoulder.
In light of the foregoing, it would be desirable to provide a tool and method to divert fluid flow out of a work string during which the work string would only have to be broken to divert and restore fluid flow. It would further be desirable to provide an annular flow diverting device that used a device that would deform under a predetermined amount of fluid pressure. It would also be desirable to provide a tool and method that only required one dart to be dropped into the work string to divert fluid flow and for which the fluid flow could be restored without the need of an additional dart.
The present invention is directed to overcoming, or at least reducing the effects of, one or more of the issues set forth above.
The object of the present disclosure is to provide a downhole tool and method to divert fluid flow out of a work string to an annulus. In one embodiment an apparatus for diverting fluid flow out of a working string is disclosed comprising a housing having an internal bore, an upper end, and a lower end wherein the housing has at least one exterior port. The apparatus includes a circulating sleeve having at least one exterior port positioned within the internal bore of the housing. The circulating sleeve is adapted to sealingly slide within the internal bore from an initial position to at least a second position. In the initial position, the circulating sleeve prevents fluid flow from the internal bore to at least one exterior port of the housing. Likewise, when the circulating sleeve is in the initial position, the housing prevents fluid flow through the at least one exterior port of the circulating sleeve. In the second position, the at least one exterior port is aligned with the at least one exterior port of the housing allowing fluid flow to the annulus.
The apparatus further includes a spring positioned to bias the circulating sleeve to its initial position. The embodiment further includes a locating sleeve having a continuous j-track positioned on the circulating sleeve. The locating sleeve being adapted to rotate around the circulating sleeve and travel along the internal bore with the circulating sleeve compressing the spring. The apparatus includes a lower pin connected to the housing and positioned within the continuous j-track and a seat connected to the circulating sleeve, the seat being adapted to catch a dart and block fluid flow through the internal bore of the housing. Fluid pressure above the seat dart moves the circulating sleeve from its initial position to at least the second position within internal bore.
The apparatus may include an upper pin connected to the housing and positioned within a slot of the circulating sleeve, wherein the upper pin radially aligns the at least one exterior port of the circulating sleeve with the at least one exterior port of the housing. The apparatus may include at least one bearing positioned between the circulating sleeve and the locating sleeve.
The dart of the apparatus may be adapted to deform under a predetermined pressure allowing the dart to pass through the seat permitting fluid flow through the internal bore of the housing. The dart may include a shearable device adapted to catch on the seat of the apparatus. The shearable device may be adapted to shear under a predetermined pressure. The dart may include a nose piece, which may be comprised of rubber.
The apparatus may include a cage housing connected to the lower end of the housing, the cage housing having a central bore in communication with the internal bore of the housing and being adapted to catch the deformed dart. The cage housing may include at least one opening in communication with the central bore and may include a structure adapted to retain the deformed dart within the cage housing. The cage housing may be adapted to catch and retain multiple deformed darts.
In one embodiment the continuous j-track of the locating sleeve may include a first shoulder, a second shoulder, a third shoulder, and a fourth shoulder. The lower pin of the apparatus may be positioned at the first shoulder of the continuous j-track when the circulating sleeve is located in its initial position. The lower pin of the apparatus may be positioned at the second shoulder of the continuous j-track when the pressure above a seated dart has moved the circulating sleeve to its second position. The lower pin of the apparatus may be positioned at the third shoulder of the continuous j-track when the pressure above the seated dart is reduced after moving the circulating sleeve to its second position. The lower pin of the apparatus may be positioned at the fourth shoulder of the continuous j-track when the pressure above the dart is increased again. The lower pin of the apparatus may remain at the fourth shoulder of the continuous j-track until the dart deforms under a predetermined pressure. The continuous j-track of the locating sleeve may include a fifth shoulder having the same axial position as the first shoulder but at a different radial location around the perimeter of the location sleeve. The lower pin of the apparatus may be positioned at the fifth shoulder of the continuous j-track after the dart deforms and passes the seat.
The upper end of the housing of the apparatus may be connected to a work string. The lower end of the cage housing of the apparatus may be connected to a work string.
One embodiment of the present invention may be used to circulate fluid into the annulus surrounding the work string at a particular location. As discussed above, drilling mud may be entering into a porous well formation instead of properly circulating the drill cuttings to the surface. The present invention may reduce the time required to inject a sealing agent the work string, circulate the sealing agent into the annulus, and return the work string to normal flow. The present invention may also reduce circulating time and increase hole cleaning efficiency in upper annuli when used in connection with a tapered work string. The present invention could be in various other applications, such as to allow increased velocity while displacing mud to clear brine fluids, as would be appreciated by one of ordinary skill in the art having the benefit of this disclosure.
One embodiment of the present disclosure is a method for diverting fluid flow out of a work string comprising the steps of disconnecting the work string at the surface, inserting a dart into the work string wherein the dart is adapted to deform under a predetermined pressure, reconnecting the work string, and pumping fluid down the work string wherein the dart travels down the work string. The method further includes catching the dart with a seat of a tool connected along the work string, the tool having a central bore in fluid communication with the work string and an exterior fluid port in communication with the central bore. The seated dart blocks the fluid flow path through the central bore of the tool. The method includes biasing a sleeve having an exterior fluid port, the sleeve being located within the housing wherein the sleeve in its initial position prevents communication between the central bore of the tool and the exterior fluid port of the tool. The method further includes increasing the fluid pressure above the seated dart and moving the sleeve along the central bore of the tool until the exterior fluid port of the sleeve aligns with the exterior fluid port of the housing. Once aligned, the method includes pumping fluid through the aligned ports.
The method may include deforming the dart caught within the seat of the tool, wherein the work string does not need to be disconnected a second time to deform the dart. The method may include reducing the fluid pressure above the dart to move the sleeve to a third position, wherein in the third position the sleeve prevents communication between the central bore of the tool and the exterior fluid port of the tool. The method may further include increasing the fluid pressure above the seated dart to move the sleeve to a fourth position, in the fourth position the sleeve prevents communication between the central bore of the tool and the exterior fluid port of the tool. The method may further include increasing the fluid pressure above the dart to a predetermined pressure causing the dart to deform and pass through the seat of the tool. The method may include returning the sleeve to its initial position and catching the deformed dart with a cage housing located below the seat. The method may further include retaining the deformed dart within the cage housing. The method may further include diverting fluid flow out of the work string a second time by inserting a second dart into the work string.
One embodiment is an apparatus for diverting fluid flow out of a work string comprising a housing having a central bore, an upper end, a lower end, and a fluid port through the housing. The apparatus includes a circulating sleeve having a fluid port through the sleeve, the sleeve being positioned within the central bore of the housing and being adapted to move along the central bore of the housing. The apparatus includes means for biasing the circulating sleeve to an initial position, wherein in the initial position the circulating sleeve prevents fluid communication between the central bore of the housing and the fluid port through the housing. The means for biasing may be a spring located within a spring housing. Alternatively, the means for biasing may be a pressurized fluid chamber or other means that would be appreciated by one of ordinary skill in the art having the benefit of this disclosure.
The apparatus includes a locating sleeve positioned between the housing and the circulating sleeve, the locating sleeve including means for retaining the circulating sleeve in a plurality of positions within the central bore. The apparatus include means for catching a dart within the housing, wherein fluid pressure above the caught dart moves the circulating sleeve from its initial position to a second position aligning the fluid port through the housing with the fluid port through the sleeve. The dart may be deformable under a predetermined position.
The apparatus may further include means for axially aligning the fluid port through a housing and the fluid port through the sleeve. The means for axially aligning may be a pin positioned within a slot or groove in the circulating sleeve. Alternatively, the means for axially aligning may be a protrusion on the circulating sleeve that is positioned within a track on the housing. The apparatus may further include means for catching the deform dart beneath the locating sleeve. The apparatus may include means for retaining the deformed dart within the means for catching the deformed dart. The means for catching the deformed dart may further comprise means for catching a plurality of deformed darts.
One embodiment of the present disclosure is a dart for use in a tool used to divert fluid flow out of a work string, the dart including a body, at least one sealing element connected around the exterior of the body, a nose connected to the down hole end of the body, and at least one shearable element connected to the exterior of the body. The shearable element is sized to be retained within a seat of a tool along the work string. The shearable element of the dart may be adapted to shear under a predetermined force. The nose of the dart may be comprised of rubber or another energy absorbing material as would be recognized by one of ordinary skill in the art having the benefit of this disclosure.
While the invention is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the intention is to cover all modifications, equivalents and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Illustrative embodiments of the invention are described below as they might be employed in an apparatus of method of diverting fluid flow out of a work string. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.
Further aspects and advantages of the various embodiments of the invention will become apparent from consideration of the following description and drawings.
The top sub 10, the housing extension 20, and the ported housing 40 each include a central bore 150 for fluid flow through the components. The ported housing 40 also circulating ports 44, an upper locating pin 41, and a lower locating pin 42. The ported housing 40 includes four ports 44 located radially around the housing, but the number of ports may be varied as would be appreciated by one of ordinary skill in the art. The bottom of the ported housing 40 is connected to a spring housing 60, which is connected on the other end to a cage housing 70. The bottom of the cage housing 70 is connected to a bottom sub 80 which is adapted to be connected to tubing or a work string. The bottom sub, the cage housing 70, and the spring housing 60 each include a central bore that permit fluid flow through the assembly.
A circulating sleeve 30 is located within the central bore 150 of the ported housing 40. The circulating sleeve 30 is adapted to sealingly slide within the central bore 150. A spring 65 within the spring housing 60 biases the circulating sleeve 30 to an initial position. In its initial position, the circulating sleeve 30 prevents fluid communication between the central bore 150 and the circulating ports 44 of the ported housing 40. Sealing elements 22 may be provided between the ported housing 40 and the circulating sleeve 30 to prevent fluid from leaking between the ported housing 40 and the circulating sleeve 30.
The circulating sleeve 30 includes fluid ports 31 that are sealed of by the ported housing 40 when the circulating sleeve 30 is in its initial position. A seat 90 having a central bore is connected to the interior of the circulating sleeve 30. In an alternative embodiment, the sleeve may be formed with an integral seat. The seat 90 is adapted to catch a dart 100 (shown in
A locating sleeve 50 is positioned between the lower portion of the circulating sleeve 30 and the ported housing 40. The locating sleeve 50 is adapted to rotate around the perimeter of the circulating sleeve 30 as the circulating sleeve 30 moves along the central bore 150 of the tool. The tool may include bushings 43 to aid in the rotation of the locating sleeve 50 with respect to the circulating sleeve 30. The end of a lower pin 42 connected to the ported housing 40 is positioned to travel in a continuous j-track 200 (shown in
The pumping of fluid at the surface is reduced or stopped when diverting the fluid flow to the annulus is no longer necessary. The reduction of fluid pressure allows the spring to push the circulating sleeve 30 to a third position. In the third position the ports 31, 44 are no longer aligned and fluid flow to the annulus is prevented. However, fluid flow through the central bore 150 of the tool is still blocked by the seat dart 100. To restore fluid flow through the tool, fluid is pumped from the surface building pressure above the seat dart. The circulating sleeve 30 is moved to a fourth position as shown in
Once the dart 100 is deformed and passes through the seat 90, fluid flow is restored through the tool releasing the fluid pressure previously above the circulating sleeve 30. The release of pressure allows the spring 65 to slide the circulating sleeve 30 back to its initial position. The movement of the circulating sleeve 30 rotates the locating sleeve 50 such that the lower pin 42 is located in the same axial location along the continuous j-track 200 as discussed below.
As discussed above, the fluid pressure is increased to deform the seated dart 100 and restore the fluid flow through the central bore 150 of the tool. The increase in fluid pressure causes the rotation of the locating sleeve 50 as well as pushing the locating sleeve 50 and the circulating sleeve 30 down the central bore compressing the spring 65. The rotation and movement of the locating sleeve 50 positions the lower pin 42 at the fourth shoulder 4. The locating sleeve 50 will remain in this position until the dart 100 is deformed and moves past the seat 90. The release of pressure allows the spring 65 to push the locating sleeve 50 and the circulating sleeve 30 back to its initial location. The movement and rotation of the locating sleeve 50 positions the lower pin 42 to a fifth shoulder 5. The fifth shoulder 5 is located at the same axial distance along the locating sleeve 50 as the first shoulder 1. The j-track 200 is repeated on the other side of the locating sleeve 50. The continuous j-track 200 provides that the device may be cycled from diverting flow out of the tool back to flow through the central bore 150 of the tool with the use of a single dart 100.
Although various embodiments have been shown and described, the invention is not so limited and will be understood to include all such modifications and variations as would be apparent to one skilled in the art.
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