Gravel packing method using vibration and hydraulic fracturing

A gravel packing method combining fracturing is described. A gun having an exterior auger is used to perforate. With the gun in place, the gravel is positioned around it and the formation is fractured, pushing the gravel into the fractures. The gun is rotated out of the gravel using the auger. A screen with an external auger is run in and rotated into the packed gravel in the wellbore while being vibrated at the same time. After the screen is advanced into position the vibrator is removed and a flapper closes to minimize fluid loss into the formation. A production string and packer are tagged into the screen and production begins.

FIELD OF THE INVENTION

The field of the invention is gravel packing a wellbore and more particularly using fracturing to deliver the gravel into the formation and vibration to insert a production screen.

BACKGROUND OF THE INVENTION

In completing wells having production or injection zones which lie adjacent incompetent subterranean formations (i.e. formations formed of an unconsolidated matrix such as loose sandstone or the like) or which lie adjacent formations which have been hydraulically-fractured and propped, serious consideration must be given to the sand control problems which will almost certainly arise during the operational life of the well. These problems arise when large volumes of sand and/or other particulate material (e.g. backflow of proppants from a hydraulically-fractured formation) dislodge from the formation and become entrained in the formation fluids and are produced therewith into the wellbore. These produced materials are highly detrimental to the operation of the well and routinely cause erosion, plugging, etc. of the well equipment, which, in turn, leads to high maintenance costs, and considerable downtime of the well.

While many techniques have been proposed for controlling sand production in a well, probably the most widely-used is one which is generically known as “gravel packing”. Basically, a gravel pack completion is one wherein a fluid-permeable liner (e.g. screen, perforated liner, slotted liner, pre-packed screens, combinations thereof, or the like) is positioned within the wellbore (open or cased) adjacent the incompetent or fractured zone and is subsequently surrounded by aggregate or particulate material through some means of circulation (collectively called “gravel” or, more generally, “proppant”). As known in the art, the gravel particles are sized to block or filter out the formation particulates which may become entrained in the produced fluids while the openings in the liner are sized to block the gravel from flowing into the liner. This two-stage filtration system is commonly known as a “gravel pack”.

There are two basic, well-known techniques for installing a typical gravel pack completion in a wellbore. A first of these techniques involves positioning the fluid-permeable liner in the wellbore before placing the gravel around the liner to form the gravel pack. The other technique involves placing the gravel in the wellbore first and then driving, rotating, or washing the liner into the gravel to form the gravel pack.

While both of these techniques have been widely used, both require the circulation of fluid during installation. For example, where the liner is positioned first in the wellbore, a slurry of gravel and a carrier fluid may be pumped down and out through a “cross-over” sub into the annulus formed between the liner and the cased wall (cased hole) or the bore wall (open hole). The openings in the liner allows only the carrier fluid to flow from the annulus into the liner while the gravel is strained from the fluid and is deposited within the annulus to form the gravel pack. The gravel can also be placed by flowing the gravel directly into the annulus around the liner from the surface or through open-ended tubulars, which extend down the wellbore.

Where the gravel is placed in the wellbore first, the liner is lowered on a workstring and is washed or driven into place while fluid is being pumped down the workstring and out the bottom of the liner. This circulating fluid (i.e. jetting action) is necessary to “fluidize” the pre-positioned or preset gravel so that the liner can be lowered into and through the gravel to form the gravel pack. Unfortunately, since the fluid flows through the workstring, the pumping must be stopped each time an additional stand of workstring must be added to lower the liner further into the gravel. While the pumping is stopped, the gravel settles and in many instances, cannot be adequately “re-fluidized” upon the resumption of pumping to allow any deeper placement of the liner into the gravel.

Since both techniques require the pumping and/or circulation of fluid under pressure during installation, both may experience severe fluid loss problems, especially when used to complete zones adjacent formations having normal or below normal pressures or pressures which are below the hydrostatic pressure of the completion fluids in the wellbore. For example, in placing gravel around a preset liner, the loss of expensive completion fluids to an underpressured formation (i.e. formation having a pressure less than the fluid pressure in the wellbore) can be excessive. The use of known loss-circulation materials in the gravel slurry is limited since such materials severely hinder the placement of the gravel around the liner. Where the gravel is positioned first, the fluid losses during the high pressure jetting required to “fluidize” the preset gravel also can be excessive. In both cases, these fluid losses not only result in increased costs due to the loss of the expensive completion fluids, themselves, but also contribute to severe formation damage in many cases thereby reducing the productivity and/or operational life of the completed well.

To counteract the above-described problems, U.S. Pat. No. 5,036,920 disclosed a screen with an external auger to allow the gravel to be deposited without circulation, so as to minimize fluid loss. Thereafter, the screen was rotated into the gravel to form the gravel pack without the need to circulate to fluidize the gravel. Augers have been used on perforating guns to facilitate extracting them after they have been shot and debris collects in the annular space surrounding them. This use of an auger on a perforating gun is shown in U.S. Pat. No. Re. 34,451. In this reference, the well is brought in to remove debris from perforating and then gravel is spotted in position and then the slurry is pumped into the perforations. Another technique is to deposit the gravel after placing the screen and then use occasional vibration to evenly distribute the deposited gravel in the annulus.

One technique of gravel deposition and dispersal into the perforations is to use fracturing. The gravel is dispersed using high pressure and flow rates. Hydraulic fracturing techniques of various types are described in several U.S. Patents, such as: U.S. Pat. Nos. 3,933,205; 4,550,779; 5,228,510; 5,617,921; 5,598,891 and 5,669,448. Various sensors can be employed to monitor the fracture packing operation, as described in WO 02/06593 A1.

More recently deposition of gravel by fracturing has become more prevalent for exclusion of produced sands in areas prone to sand production. The reason for this shift in technique is the higher productivity realized with the fracturing technique. Fracturing effectively penetrates to hundreds of feet into the formation to bypass previously induced damage mechanisms. However, fracturing has brought on other problems such as crossover tool erosion, casing erosion, screen erosion, stuck crossover tools, downhole real time pressure monitoring problems and fluid losses to the formation.

The method of the present invention mitigates at least some of these prior problems. The gravel is placed in position after under-balanced perforating. Fracturing is done with the gun in position and the gun is subsequently extracted. The screen is inserted into the preset gravel that has been pushed into the perforations and augered into the gravel with the help of vibration. Subsequently, the vibrator is removed and a production packer is tagged into the screen for subsequent production. These and other aspects of the present invention will be more apparent to those skilled in the art from a review of the description of the preferred embodiment, which appears below.

SUMMARY OF THE INVENTION

A gravel packing method combining fracturing, using flights, rotation and vibration is described. A gun having an exterior auger is used to perforate. With the gun in place, the gravel is positioned around it and the formation is fractured, pushing the gravel into the fractures. The gun is rotated out of the gravel pack using left hand auger flights. A screen with an external auger is run in and rotated into the packed gravel in the wellbore while being vibrated at the same time. After the screen is advanced into position the vibrator is removed and a flapper closes to minimize fluid loss into the formation. A production string and packer are tagged into the screen and production begins.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1illustrates an isolation packer10delivered on a tubing string (not shown). Below the packer is a crossover12that permits gravel14to exit ports16to enter annulus18as shown in FIG.2. Arrows20represent the flow of gravel and fracturing fluid into annulus18, which occurs after the gun22, is in the desired position shown in FIG.1. Gun22has an exterior auger24to facilitate its extraction after being shot and creating perforations26. An isolation packer28may be set below the perforating gun22.

FIG. 2shows the gravel14forced into the perforations26as part of the fracturing process initiated from the surface with the introduction of pressurized fluid and the gravel14. Fracturing begins after well fluids are first reversed out. As a result of the fracturing, the gravel14is forced into the perforations26to hold them open and promote production. The gravel14also reduces sand production from the formation. At the end of the fracturing operation when the gravel14is deposited in the perforations26, as desired, the gun22is removed preferably by right hand rotation to help further pack the gravel14in the perforations26. The rotating flights of auger24give an exit push to the gun22while at the same time the reaction force helps to compress the gravel14further into the perforations26.

With the gun22removed, a screen30having an auger32that extends over a screen portion34and a blank portion36is inserted. A removable vibrator38is connected to the hook up nipple40. The hook up nipple is rotationally locked to the knock out isolation valve42. Inside valve42is a flapper44, which closes after removal of the vibrator38. As shown inFIG. 4, the screen30is preferably rotated to the right to allow auger32to assist the screen30in penetrating the gravel14. The vibrator38is activated continuously or intermittently, as needed to help in the advancement of the screen30. Vibrator assembly38holds flapper44open during this operation. The entire assembly shown inFIG. 4is rotated from the surface to advance screen30using auger32in conjunction with vibration from the vibrator38. Vibrator38may be actuated by circulation, reverse circulation, or a locally provided power source. Any type of known vibrator can be used. The more contact with screen30that can be arranged with vibrator38and the higher the amplitude of the vibration, the easier will it be to insert the screen30into the gravel14which has been previously packed during the fracturing operation.

FIG. 5shows dropping a ball46and pressuring up on string48to release from receptacle50. The vibrator38is removed with the string48and flapper44falls shut. Closing flapper44reduces fluid loss from above into the formation. InFIG. 6the screen30is ready to receive a production string and packer (not shown) so that production can begin.

Those skilled in the art will recognize the advantages of the disclosed method. The erosion risk is reduced as the fracturing is completed with the gun22still in position and before the screen30is inserted. Cleaner perforations are possible and the possibility of bridging and voids in the gravel14are reduced. The auger action in removing the gun22and inserting the screen30help to evenly distribute the gravel14in the annulus18and mechanically drive proppant into the perforations. The presence of the augers24and32allow respectively for removal of the gun22or the screen30, should that at any time become necessary. The need to pump pills into the formation, which can damage it and fill perforations with undesirable materials, are also minimized when fracturing the formation with the perforating guns across the production interval. With all perforations open to flow, out of phase perforations from the fracture wings can also be packed either during the pumping process or mechanically during the gun removal.

The augers such as24and32can be segmented or continuous and can have a constant pitch or variation in pitch along its length. The flights may be enclosed or open in various locations either above or below or both so as to act as a shunt tube to eliminate bridging by giving the gravel alternate paths to redistribute it when being deposited under pressure.FIG. 7illustrates hollow flights31that have an opening33in the top and multiple bottom openings35at different elevations to discharge gravel that has entered opening33. There can be many inlet openings such as33. This can be accomplished by making the flights31discontinuous. The pitch and diameter of flights31can vary. The direction of rotation and the speed can be varied. The augers can be rotated in series in opposed directions to facilitate insertion of the screen30or removal of the gun22. Rather than using flights31, the augers can comprise a plurality of extending rods that protrude radially and create a similar effect to assist insertion of screen30or removal of gun22.

The foregoing disclosure and description of the invention are illustrative and explanatory thereof, and various changes in the size, shape and materials, as well as in the details of the illustrated construction, may be made without departing from the invention.