SURFACEDEPLOYED CEMENT SEPARATIONPLUG
Inventor: Michael E. McMahan
BACKGROUND OF THE INVENTION
Field of the Invention - The present invention is in the field of devices used in placing a cement plug in an open hole well bore, or in a casing in a well bore.
Background Art - It is sometimes desirable to segregate an uphole portion of a well bore from an adjacent downhole portion. Typically, the well bore or casing is full of drilling fluid having a density calculated to balance the formation pressure. Cement slurry is pumped to the location where the operator desires to segregate the well bore. A cement plug is deposited at this location and left to hydrate or harden. Usually, the density of the cement slurry is greater than the density of the drilling fluid. So, the cement tends to drift or migrate downwardly in the well bore, with the result that the cement plug is formed at a deeper location than desired. Further, because of this migration of the cement slurry into the drilling fluid, drilling fluid can flow upwardly through the cement slurry, and the cement plug formed may not completely extend across the diameter of the well bore. Still further, mixing of the drilling fluid with the cement may contaminate the cement plug and reduce its strength. Therefore, when a well bore or casing is to be plugged with cement, it is desirable to be able to limit or eliminate the migration or contamination of the cement slurry.
One known remedy for the cement migration or contamination problem is to place a barrier at the desired location for the cement plug, and then to place the cement slurry on top of the barrier. The barrier might be a mechanical apparatus or a jelled plug. Such mechanical barrier devices usually suffer from the disadvantage that the exact configuration and dimensions of the hole must be known, so they must be installed in a cased hole. Jelled barriers may take a long time to set up before the cement slurry can be placed. At least one mechanical barrier is also known, which consists of two sets of thin strips of metal, one angled uphole and one angled
downhole, which flex and press outwardly against the walls of the bore hole or casing. This device relies upon additional uphole and downhole pumpable plugs to pump the barrier into position, and it is often difficult to determine when the barrier has been placed at the desired location. Further, because the device is centered only by the two sets of flexed metal strips, it may not be accurately centered in the hole. Finally, because of the downhole set of flexible strips, this device can become snagged in some types of work string.
BRIEF SUMMARY OF THE INVENTION The present invention comprises a pumpable barrier which has a plurality of flexible elongated flat strips, and an annular seal for sealing against the bore hole wall. The annular seal, which can be mounted at the uphole or downhole end of the barrier, provides a fluid barrier against which hydraulic pressure can be applied, to pump the barrier downhole, through a work string, to the desired location. This eliminates the need for pumpable plugs to be used to place the barrier downhole. The plurality of elongated flat strips are attached, at one end, to the body of the barrier, with their free ends being oriented toward the trailing end of the barrier. This allows the barrier to be pumped through any type of work string without snagging. The flat strips can be constricted closely to the body of the barrier, to allow pumping of the barrier through the work string, or they can be allowed to flex outwardly, to contact and press against the wall of the well bore. Once the barrier has been pumped downhole to the desired location, it exits the end of the work string, and the elongated strips are released to flex outwardly. Cement slurry placed above the barrier will not migrate through the barrier, because the spacing between the flat strips is too small to allow the passage of the viscous slurry. This allows the cement plug to completely set up, at the desired location, completely covering the cross section of the casing or well bore.
If desired, the barrier can be landed in a landing sub at the downhole end of the work string, then released from the landing sub by the shearing of a shearable device, such as a shear pin. Landing of the barrier in the landing sub results in an increase in pressure, signaling the operator that the barrier has reached the desired location.
Release of the barrier from the landing sub results in a decrease in pressure, signaling the operator that the barrier has been put in place.
The novel features of this invention, as well as the invention itself, will be best understood from the attached drawings, taken along with the following description, in which similar reference characters refer to similar parts, and in which:
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
Figure 1 is a longitudinal section view of a first embodiment of the present invention, with flat strip elements and a leading annular seal, showing the strip elements in a constricted orientation; and
Figure 2 is a longitudinal section view of the embodiment shown in Figure 1, showing the strip elements in an expanded orientation.
DETAILED DESCRIPTION OF THE INVENTION
As shown in Figure 1, the separation barrier 10 of the present invention includes a generally cylindrical barrier body 12, a plurality of elongated flexible elements 14, and an annular fluid seal 16 on the perimeter of the body 12. The body 12 can be one piece or multi-piece, as shown. The elongated fluid separation elements 14 can be a plurality of closely spaced, overlapping flat strips of flexible material, as shown, or other expandable elements which can be arranged and spaced to prevent the migration of cement slurry therebetween. Leading ends 26 of the elongated elements 14 are attached circumferentially around the perimeter of the body 12, while trailing ends 28 of the elongated elements 14 are free to expand or flex generally radially outwardly. The elongated elements 14 are outwardly biased, either by their own stiffness or by additional biasing means. The elongated elements 14 are constrained to the constricted orientation shown in Figure 1 before the barrier 10 is placed into the work string at the well site.
The annular fluid seal 16 can be mounted either adjacent the leading end of the body 12, as shown, or it can be mounted adjacent the trailing end of the body 12. The annular fluid seal 16 shown consists of a double swab cup of flexible material such as
rubber. The annular fluid seal 16 has an outer diameter greater than the outer diameter of the constricted elongated elements 14, and a sufficiently great diameter to achieve a fluid seal against the inner diameter of a work string 18, to facilitate the pumping of the barrier 10 through the work string 18 without the use of separate pumpable plugs. The work string 18 can have a landing shoulder 20 inside a landing sub at its lower end 30. Further, the body 12 of the barrier 10 can have a landing ring 22 shearably attached thereto by means of one or more shear screws or pins 24. The landing ring 22 is shown attached to the trailing end of the body 12, but it could also be attached to the leading end. The barrier 10 and its components are sized and configured to be pumped downhole through the work string 18 until the landing ring 22 lands in the landing shoulder 20. Since the barrier 10 completely plugs the work string 18 at this point, this results in an increase in drilling fluid backpressure which is a positive indication to the operator that the barrier 10 is at the lower end 30 of the work string 18. The operator will have positioned the lower end 30 of the work string 18 at the desired location for deployment of the barrier 10, by known methods. The operator can then allow the drilling fluid pressure to increase until the shear pins 24 are sheared, releasing the barrier body 12 from the landing ring 22, and allowing the barrier 10 to exit the lower end 30 of the work string 18, as shown in Figure 2. This allows drilling fluid to exit the work string into the larger well bore, resulting in a decrease in the fluid backpressure. This decrease in backpressure is a positive indication to the operator that the barrier 10 has been deployed at the desired location.
As the barrier 10 is deployed from the lower end 30 of the work string 18, the free ends 28 of the flexible elongated elements 14 expand outwardly toward the well bore, as shown in Figure 2. The flat strips of elongated elements 14 are closely spaced or overlapping, thereby minimizing or preventing the migration of cement slurry therebetween. The expanded elongated elements 14 can also press against the wall of the well bore with sufficient force to centralize the barrier body 12 in the well bore, insuring complete blockage of the cement slurry. Cement slurry placed above, or uphole from, the barrier 10, with the elongated elements 14 in this expanded orientation, will stay in place long enough to set up, thereby effectively segregating the uphole portion of the well bore from the downhole portion.
If desired, two or more such barriers may be pumped downhole successively, to prevent migration or contamination of cement plugs at various depths.
While the particular invention as herein shown and disclosed in detail is fully capable of obtaining the objects and providing the advantages hereinbefore stated, it is to be understood that this disclosure is merely illustrative of the presently preferred embodiments of the invention and that no limitations are intended other than as described in the appended claims.