Remotely operated multi-zone packing system

BACKGROUND OF THE INVENTION

1. Technical Field

The present invention relates to a remotely operated multi-zone packing system used in multi-zone gravel pack, frac pack, and similar applications in oil field wells. Specifically, the present invention allows for remote operation of gravel pack, frac pack, or similar assemblies in multi-zone applications, thus eliminating the requirement to physically relocate a work string to each zone of interest to accomplish various phases of the completion.

2. Description of Related Art

Gravel pack assemblies and frac pack assemblies are commonly used in oil field well completions. A frac pack assembly is used to stimulate well production by using liquid under high pressure pumped down a well to fracture the reservoir rock adjacent to the wellbore. Propping agents suspended in the high-pressure fluids (in hydraulic fracturing) are used to keep the fractures open, thus facilitating increased flow rates into the wellbore. Gravel pack completions are commonly used for unconsolidated reservoirs for sand control. Gravel packs can be used in open-hole completions or inside-casing applications. An example of a typical gravel pack application involves reaming out a cavity in the reservoir and then filling the well with sorted, loose sand (referred to in the industry as gravel). This gravel pack provides a packed sand layer in the wellbore and next to the surrounding reservoir producing formation, thus restricting formation sand migration. A slotted or screen liner is run in the gravel pack which allows the production fluids to enter the production tubing while filtering out the surrounding gravel.

A typical single-zone gravel pack completion is illustrated in FIG.

1

.

FIG. 1

is a schematic cutaway representation showing a perforated wellbore casing

2

with perforations

12

shown extending into a single zone of interest

10

. Within the wellbore casing

2

a tube

4

has been placed on which is attached a screen

6

. The gravel

8

is shown packed into the perforations

12

in the zone of interest

10

and surrounding the screen

6

. The gravel

8

is an effective filter of formation fluids, because the formation sand, which would otherwise flow with the production fluid, is largely trapped at the interface with the gravel

8

.

One specific type of gravel pack procedure is called a squeeze gravel pack. The squeeze gravel pack method uses high pressure to “squeeze” the carrier fluid into the formation, thereby placing gravel

8

in the perforation tunnels

12

of a completed well and the screen/casing annulus. The frac pack method is very similar, except the “squeeze” is carried out at even higher pressures with more viscous fluid in order to fracture the reservoir rock. Consequently, the down-hole assembly used for these two procedures is frequently the same, and the procedures will be discussed as examples interchangeably in this disclosure.

A typical gravel pack or frac pack assembly is presently run into the well on a work string. The work string is commonly a length of drill pipe normally removed from the well once the packing job is complete. The work string assembly contains a means for setting the packer and a crossover tool to redirect the treatment from within the work string into the formation. This is illustrated by

FIG. 2

, which shows a schematic cutaway of a basic frac pack assembly for a single zone of interest

210

application. At the upper portion of the assembly the work string is a single tube or pipe

214

(which is also referred to herein as the inner tubing). Further down the assembly this single tube

214

is attached to and enclosed by a middle concentric tube

216

. The now inner tube

214

and middle tube

216

are integral to the work string and can be moved vertically through the wellbore annulus

202

by manipulation at the rig level. The middle tube

216

is initially attached to or pinned to an outer concentric tube

204

when the assembly is landed in the well. Immediately above the point where the middle tube

216

and the outer

204

begin to interface concentrically are seal points

218

,

230

, providing pressure seals between the middle concentric tube

216

and the outer concentric tube

204

. Once the assembly is landed and set in place, the temporary attachment between the middle tube

216

and the outer tube

204

can be broken, for example by applying tension to a shear pin by pulling the middle tubing

216

upward. The seal points

218

,

230

provide pressure isolation between the middle tubing

216

and the outer tubing

204

even as the work string is moved up and down in the assembly.

Attached to the outer tubing

204

is a hydraulic set packer

220

. When “set,” a procedure that will be described momentarily, the hydraulic set packer

220

provides a complete seal between the outer tubing

204

and the wellbore casing

202

. Below the hydraulic set packer is a fluid crossover port

240

, formed by passages through the inner tubing

214

and the concentric middle tubing

216

, which allows fluid to crossover from the inner tubing

214

through the concentric middle tubing

216

without coming into physical contact with any fluid that may be passing through the annulus between the inner tubing

214

and the concentric middle tubing

216

. A gravel pack port

224

, which is opened and closed with a closing sleeve

226

, which is operated by a shifting tool (not shown), provides communication for fluid exiting the crossover port

240

into the wellbore annulus

202

. This gravel pack port

224

, although shown in the open position, may be initially in the closed position with the closing sleeve

226

sealing the port

224

when the assembly is landed in the well. In the closed position, fluid transported down the inner tubing

214

is diverted by a plug

236

, passes through the crossover port

240

, and is isolated between the hydraulic set packer

220

and a seal

230

located below the port

224

. Thus, pressure can be built up inside this isolated segment of the outer tubing

204

. The packer

220

is hydraulically actuated or “set” by applying fluid pressure until the outer tubing

204

is pressure isolated by the packer's

220

seals within the wellbore annulus

202

.

After the packer

220

is set, the gravel packing or frac packing job can be initiated by opening the gravel pack port

224

by shifting open the closing sleeve

226

. This is typically accomplished by physically manipulating the closing sleeve

226

with a shifting tool (not shown) attached to the exterior of the middle tubing

216

by raising or lowering the work string (which consists of the inner tubing

214

, the middle tubing

216

, and all integral components shown in FIG.

2

). Once the closing sleeve

226

opens the port

224

, the proppant for the gravel pack or frac pack completion is pumped down the inner tubing

214

, through the crossover port

240

, out the gravel pack port

224

, and into the wellbore annulus

202

, as indicated by flow arrows

250

in FIG.

2

. Below the closing sleeve

226

and gravel pack port

224

, the outer tubing

204

comprises a screen or slotted liner

206

, similar to the screen

6

illustrated in FIG.

1

. Therefore, during the “frac job” the proppant is forced into the perforations

212

of the wellbore casing

202

and begins to fill the cavity between the screen

206

and the wellbore casing

202

. The carrier fluid

250

for the gravel, after being filtered by the screen

206

, may be circulated through the annulus between the inner tubing

214

and the concentric middle tubing

216

, which has an open end

232

inside the screen

206

in a single zone of interest application. The fluid

250

goes past a ball

234

near the bottom opening

232

of the middle tubing

216

, which acts as a check valve preventing fluids from back flowing from the annulus between the inner tubing

214

and the concentric middle tubing

216

back into the screen. The circulation of the carrier fluid exits through a port

238

above the seal point

218

.

The gravel pack procedure becomes more complex when it is necessary to accomplish a frac pack or gravel pack completion on multiple zones of interest within the same wellbore.

FIG. 3

illustrates a schematic cutaway of a typical prior art multi-zone frac pack assembly used for this purpose.

FIG. 3

shows two zones of interest

310

,

311

isolated by hydraulic set packers

320

,

321

,

322

. Packers

321

that separate zones of interest

310

,

311

are typically called isolation packers, while the packer

322

which is set below the last zone of interest in the wellbore is known as a sump packer and is set before landing the gravel pack assembly. Common to each zone of interest

310

,

311

on the multi-zone assembly is a gravel pack port

324

,

325

with associated closing sleeve

326

,

327

and a screen

306

,

307

. The screens

306

,

307

are placed opposite each zone of interest

310

,

311

. As with the single zone of interest assembly illustrated by

FIG. 2

, the multiple zone assembly comprises inner tubing

314

and middle tubing

316

, which are attached above the top packer

320

. Outer tubing

304

is shown which is initially fixed in position relative to the other concentric tubes (work string) when landing in the well. Although the upper gravel pack port

324

is shown closed while the lower gravel pack port

325

is shown open in

FIG. 3

for illustrative purposes, all of the gravel pack ports

324

,

325

are initially in the closed position when the assembly is landed in the well.

To begin the frac pack or gravel pack completion, each of the isolation packers

320

,

321

must be set. This is accomplished by starting at the lowest zone

311

to be treated with the crossover tool

340

in the position illustrated by FIG.

3

. Since the gravel pack port

325

is initially closed, fluid

350

pumped down the inner tubing

314

is diverted by a plug

336

and flows through the crossover port

340

into the outer tubing

304

, where it is contained between seals

331

and the packer

321

. Increasing the fluid pressure thereby actuates or “sets” the hydraulic set packer

321

. The crossover port

340

is then raised to the next zone

310

by lifting the entire work string (comprising both the inner tubing

314

and the middle tubing

316

) in order to set the next packer

320

by the same method. A series of bore seals

317

,

318

,

319

ensure a proper pressure seal between the middle tubing

316

and the outer tubing

304

while the work string is manipulated.

Once all of the packers

320

,

321

have been set, the crossover port

340

is returned to the lowest zone of interest

311

in order to begin the packing stage. Again, this is accomplished by physically lowering the entire work string. All of the gravel pack ports

324

,

325

are now in the open position by virtue of, for example, the actuation of a closing sleeve

326

,

327

by a shifting tool (not shown). With the crossover port

340

located in the lowest zone of interest

311

, proppant

350

is forced from the inner tubing

314

, through the crossover port

340

, out the open port

325

, and into the wellbore annulus

302

. The return fluid

350

“circulates” by traveling through (and is filtered by) the screen

307

, into the open end

332

of the middle tubing

316

, past the ball

334

and plug

336

, through the annulus between the inner tubing

314

and the concentric middle tubing

316

, and out the exit port

338

, just as in the single zone assembly shown in FIG.

2

. Once the packing job is completed in the lowest zone of interest

311

, the crossover port

340

is moved to the next zone of interest

310

(by raising the work string) to accomplish a similar procedure, and so on until all zones are completed.

Although

FIG. 3

shows only two zones of interest

310

,

311

, the procedure is the same, and the fixed assembly components (packers, gravel ports, closing sleeves, and screens) are simply duplicated, regardless of the number of zones treated during the packing job. Isolation packers between the zones are set separately by pulling up the work string, and then a packing job is completed on each zone separately by physically placing the crossover port

340

within the zone to be treated and opening the adjacent gravel pack port.

The physical manipulation of the work string up and down through the outer tubing

304

and wellbore casing

302

poses several practical problems with the prior art multi-zone assemblies. The proppants mixed in the fluids

350

used in these applications are extremely abrasive and erosive. The tubing

314

,

316

illustrated in

FIG. 3

is, of course, not a continuous piece of tubing. Rather, the tubing

314

,

316

is made up of individual segments with connections and seals located at the intersection of each segment. These seals are subject to wearing as the work string is moved up and down in such an erosive environment. Consequently, the seals are prone to failure thus compromising the integrity of the assembly. There is also the potential that the work string might get stuck while being moved up and down to accomplish various phases of the completion. The need to physically manipulate the crossover port

340

up and down to the various zones of interest, each time taking steps to insure proper placement of the port

340

, is also an involved procedure requiring additional rig time and, consequently, additional cost to the completion job.

A need exists, therefore, for a multi-zone pack assembly that can be remotely activated without the necessity of physically raising and lowering the work string and crossover tool to each zone of interest. Such invention would greatly reduce the wear on the tubing seals and eliminate the potential of the work string getting stuck within the outer tubing during the packing job. Such invention could also save time and completion related expenses by simplifying the steps required to perform each stage of the completion.

SUMMARY OF THE INVENTION

The present invention relates to an improved multi-zone gravel pack, frac pack and like assemblies that operate without the necessity of raising and lowering a working string and crossover tool to various zones of interest. The invention uses the unique design of having a crossover tool on the working string collocated at every zone of interest combined with remotely activated closing tools.

One embodiment of the invention discloses a circulation valve, which allows for carrier fluid to either circulate after passing through the screen or flow through from a lower portion of the assembly, or be “reverse circulated” back up the workstring, and a remotely activated crossover port at each zone of interest. The closing sleeve on the gravel pack port allowing access to the wellbore annulus is opened and closed through use of traditional closing tools and minor manipulations of the work string. However, the work string does not need to be raised and lowered as between zones of interest. Therefore, the wear and tear on the work string is greatly reduced and the time required to perform the setting of each isolation packer as well as the gravel pack completion in each zone is reduced.

Another embodiment of the invention requires no movement of the work string relative to the outer tubing. Again, in the circulation embodiment, there is a crossover tool collocated at every zone of interest. Rather than using a closing sleeve on the gravel pack port and a circulation valve, the second embodiment uses an iris valve or other similar means to divert flow within the washpipe and a remotely actuated closing sleeve at the gravel pack port.

The invention is versatile and can be tailored to meet the requirements of each specific well completion. By eliminating the need to move the work string and single crossover tool to each zone of interest in order to set each individual packer and later perform the gravel pack job for each zone, this invention greatly reduces the wear and tear on the work string seals and eliminates the possibility that the work string might become stuck during physical manipulation. Further, by allowing the stages of a multi-zone packing job to be accomplished simultaneously, and by eliminating the time required to raise and lower the working string, this invention is a great improvement over the prior art in efficiency and cost effectiveness.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and for further details and advantages thereof, reference is now made to the following Detailed Description taken in conjunction with the accompanying drawings, in which:

FIG. 1

is a schematic representation of a prior art gravel pack completion in a single zone of interest application.

FIG. 2

is a cross sectional schematic of a prior art single zone squeeze pack assembly.

FIG. 3

is a cross sectional schematic of a prior art multi-zone squeeze pack assembly.

FIG. 4

is a cross sectional schematic of an embodiment of the present invention incorporating a remotely activated crossover valve.

FIG. 5

is a cross sectional schematic of an embodiment of the present invention incorporating an iris plug in a non-circulation application.

FIG. 6

a

is an overhead perspective view of an open iris plug.

FIG. 6

b

is an overhead perspective view of a closed iris plug.

FIG. 7

is a cross sectional schematic of an embodiment of the present invention incorporating an iris plug in a circulation application.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 4

illustrates one embodiment of the present invention showing two zones of interest

410

,

411

. As with the prior art assembly shown in

FIG. 3

, these zones of interest

410

,

411

are isolated by packers

420

,

421

,

422

. Between each packer

420

,

421

,

422

there are three lengths of concentric tubing.

FIG. 4

shows an inner tubing string

414

, a middle tubing string

416

, and an outer tubing

404

. The inner tubing

414

and middle tubing

416

are, as with the prior art method of

FIG. 3

, connected together and integral to the work string. Proppant

450

flows from the top of the assembly down the inner tubing

414

for use in both setting the packers

420

,

421

and performing the frac or gravel pack. The filtered carrier fluid is recirculated through the assembly via the middle tubing

416

.

Referring to the portion of the assembly associated with the upper zone of interest

410

, a crossover port

440

is provided to allow flow of the fluids

450

from the inner tubing

414

past the middle tubing

416

and inside the outer tubing

404

. The outer tubing has a gravel pack port

424

, which is initially in the closed position when the assembly is landed in the well, and below the port

424

a seal

430

isolating a segment of the outer tubing

404

between the packer

420

and the seal

430

. Therefore, when fluids

450

go through the crossover port

440

and into the outer tubing

404

, the hydraulic set packer

420

can be set as similarly described when discussing prior art methods.

FIG. 4

also shows a screen

406

,

407

opposite each zone of interest and the same basic three concentric tube arrangment shown in the prior art multi-zone system illustrated in FIG.

3

. The invention illustrated in

FIG. 4

contains, however, two unique features that eliminate the need to raise and lower a crossover tool into each zone to perform setting the packer and, later, to perform the packing job for each zone. First,

FIG. 4

shows that a crossover port

440

,

441

is located adjacent to a gravel pack port

424

,

425

at every zone

410

,

411

. This crossover port

440

,

441

is remotely activated to open and close. Closing the crossover port

440

,

441

closes the communication of fluids

450

between the inner tubing

414

and the outer tubing

404

, while opening the crossover port

440

,

441

permits fluids

450

to flow from the inner tubing

414

, across the middle tubing

416

, and into the outer tubing

404

. Consequently, a crossover of fluids

450

into any specific zone

410

,

411

can be accomplished by selecting a specific crossover tool to open while closing the other crossover tools. The second unique feature is three way circulation valves

460

,

461

located between the inner tubing

414

and middle tubing

416

below each screen

406

,

407

. These three way circulation valves

460

,

461

allow either communication of fluids

450

to the annulus between the inner tubing

414

and middle tubing

416

after passing through the crossover ports

440

,

441

, gravel pack ports

424

,

425

, and screens

406

,

406

, or “pass through” communication to or from below the valves

460

,

461

entirely through the annulus between the inner tubing

414

and the middle

416

, or “pass through” communication to or from below contained entirely within the inner tubing

414

, depending on the position selected. As with the crossover ports

440

,

441

, the circulation valves

460

,

461

are remotely activated. The remote activation for both the crossover ports

440

,

441

and the circulation valves

460

,

461

could be accomplished by either a hard wire arrangement or wireless communication.

In practice, the assembly illustrated by

FIG. 4

is made up at the surface and run into the hole in one trip with the closing sleeves

426

,

427

initially in a position sealing off the gravel pack port

424

,

425

, as illustrated for the upper sleeve

426

in FIG.

4

. After the assembly is run to the proper depth and landed, a ball

434

is dropped from the rig level to set a packer

420

at the top of the completion, such as a Versa Trieve packer. This ball seats at a hydraulic setting tool (not shown) in order to actuate the packer

420

. The ball

434

is then released and dropped to a tapered ball seat

435

at the bottom of the work string where it lands and seals off the work string.

The remaining isolation packers

421

can now be set. Since the bottom of the assembly is plugged by the setting ball

434

and all the gravel pack ports

424

,

425

are initially closed by the closing sleeves

426

,

427

, the isolation packers

421

(assuming there are more than one not yet set) can all be set simultaneously with all crossovers ports

440

,

441

open or sequentially by selectively operating the crossover ports

440

,

441

such that only one is open at a time.

By way of example, it will be assumed that the upper-most packer

420

was not previously set as described above, but, rather, is an isolation packer located below another zone of interest not shown on FIG.

4

. Under this assumption,

FIG. 4

illustrates only two zones

410

,

411

of interest in a multi-zone completion of three or more zones. The two illustrated isolation packers

420

,

421

, along with any other isolation packers in the multi-zone system, could be set simultaneously by remotely opening all the crossover ports

440

,

441

, with the gravel pack ports

424

,

425

closed. Fluid pressure is now communicated from the inner tubing

414

, through the crossover ports

440

,

441

, and is isolated in the outer tubing

404

between the packers

420

,

421

, and their respective seals

430

,

431

. Consequently, all of the isolation packers

420

,

421

can be set simultaneously. Alternatively, each isolation packer

420

,

421

could be set individually by only opening the crossover ports

440

,

441

immediately below the isolation packer in question.

After all the isolation packers

420

,

421

are set, the closing sleeves

426

,

427

are opened in the traditional manner by lifting the work string (comprising the inner tubing

414

and outer tubing

416

) sufficiently so that a shifting tool (not shown) can be raised above the sleeve and then slacked back off to the original position. As with prior art assemblies, bore seals

417

,

418

,

419

maintain the seal between the work string and the outer tubing

404

.

Referring to the lower zone of interest

411

and its respective gravel pack port

425

(shown in the open position in FIG.

4

), the gravel packing is now accomplished by opening the crossover port

441

at the lower zone

411

with all other crossover ports

440

closed. At this point all the up-well circulation valves

460

are selected for the inner-tube-only “pass through” communication position. The circulation valve

461

below the screen

407

in the first zone

411

, however, is placed in the “circulate” position. Consequently, proppant laden fluid

450

flows down the inner tube

414

, through the lowest crossover port

441

, out the open gravel pack port

425

, and performs the frac or gravel pack job in the zone of interest

411

between the two packers

420

,

421

. The carrier fluid

450

is then filtered through the screen

407

, thus passing through the outer tubing

404

. Since the circulation valve

461

has been set to communicate with the outer tubing

404

, the filtered carrier fluid

450

next travels through the circulation valve

461

and is diverted up the annulus between the inner tubing

414

and the middle tubing

416

. Carrier fluid

450

continues passing by all of the up-well crossover ports

440

,

441

, through all the up-well circulation valves

460

, and will eventually exit the assembly above the upper packer

420

into the wellbore annulus

402

by way of an exit port

438

.

A reverse circulation mode, used to clear away excess fluids and proppant left after packing the first zone

411

, may be achieved by selecting a position for the valve

461

which closes communication with the screen

407

and opens communication between the inner tubing

414

and the annulus between the inner tube

414

and the middle tube

416

. Fluids

450

may be reverse circulated by applying pressure through the port

438

, which may cause flow down said annulus and back up the inner tubing

414

and workstring above.

The gravel pack for the next zone

410

is accomplished by repeating this process. It is not necessary to raise the work string to the next level, since there is a crossover port

440

,

441

collocated at every zone of interest

410

,

411

. The crossover port

441

at the lower zone

411

is closed and the crossover port

440

at the next zone

410

is opened. The circulation valve

460

collocated with this zone

410

is moved from the flow through position to the circulate position. Since the gravel pack port

424

is now open, the packing job is accomplished as described above.

Once all of the zones of interest

410

,

411

have been treated, the work string is then removed by first opening all crossover ports

440

,

441

and circulation valves

460

,

461

. The work string is then pulled out of the hole. All closing sleeves

426

,

427

are closed at this time. Next, a conventional concentric string is run into the completion including seals for isolation between zones and any other equipment required for selective production.

Another embodiment of this invention is illustrated in FIG.

5

.

FIG. 5

shows a multi-zone squeeze pack assembly without circulation. This embodiment has an inner tubing string

514

and an outer tubing

504

. Each zone of interest

510

,

511

is isolated by packers

520

,

521

,

522

.

2

There is a crossover port

570

,

571

at each zone of interest

510

,

511

for fluid communication between the inner tubing

514

and the outer tubing

504

. There is also at each zone

510

,

511

a gravel pack port

524

,

525

for communicating between the outer tubing

504

and the wellbore annulus

502

. As with the previous embodiment, the segment of the outer tubing

504

in communication with the screen

506

,

507

is separated from the segment of the outer tubing

504

in communication with the packer

520

,

521

by a seal

530

,

531

.

The embodiment illustrated by

FIG. 5

requires no manipulation of the work string due to two unique features. First, the closing sleeves

526

,

527

are remotely actuated by, for example, electrical actuators

528

,

529

which are either hard wired or operate by wireless communication. Wireless means also include, but not be limited to, a hydrophone or air hammer that provides an acoustic signal that travels through the completion fluid or the tubing string. Activation could also be accomplished hydraulically through control lines from the surface.

FIG. 5

shows, for illustrative purposes, the upper closing sleeve

526

in the closed position while the lower closing sleeve

527

is in the open position. Second, this embodiment utilizes unique remotely operated plug valves

580

,

581

within the inner tubing

514

, an example of which is illustrated in

FIGS. 6

a

and

6

b

. A suitable tool might be the surface controlled reservoir analysis and management system tools made by Petroleum Engineering Services of Aberdeen, Scotland.

FIGS. 6

a

and

6

b

show a head on view of a plug

680

comprising an iris valve.

FIG. 6

a

shows the valve in the open position, which would allow fluids to pass through.

FIG. 6

b

shows the valve

680

in the closed position. The iris valve

680

has been closed by rotation of an interior ring

684

within an outer race

686

by an actuator contained within or attached to the plug. The plug valves

580

,

581

used in the embodiment shown in

FIG. 5

could also consist of a ball valve with remote actuator.

FIG. 5

illustrates how each isolation packer

520

,

521

is set by first closing the gravel pack ports

524

,

525

with the remotely actuated closing sleeves

526

,

527

. All of the isolation packers

520

,

521

can be set simultaneously or each one can be set sequentially. The sequential operation is performed by closing all of the plug valves

580

,

581

within the inner tubing

514

. The upper hydraulic set packer

520

is then set as fluid pressure is communicated from the inner tubing

514

, through the port

570

and is isolated in the outer tubing

504

between the seal

530

and the packer

520

. Next, the upper iris valve

580

is opened to allow fluid communication with the segment of the inner tubing

514

in the next lowest zone

511

. The packer

521

above that zone

511

could then be set by the same protocol. This procedure is followed until all of the packers

520

,

521

,

522

are set. Conversely, all of the packers

520

,

521

,

522

could be set simultaneously by closing all of the gravel pack ports

524

,

525

and opening all of the iris valves

580

,

581

.

After the hydraulic set packers

520

,

521

are set, the frac pack or gravel pack job can be accomplished in a particular zone, for example the lower zone

511

, by simply opening the gravel pack port

525

at that zone. This allows the proppant laden fluid

550

to flow from the inner tubing

514

, through the open port

571

, out the gravel pack port

525

, and into the wellbore annulus

502

. This process is repeated until each zone of interest is completed. After the packing job is done, all of the sleeves

526

,

527

are closed and the proppant remaining from the fluid

550

is removed by coil tubing or well flow when the iris plugs

580

,

581

are all opened.

FIG. 7

shows another embodiment of the invention using the plug valves

780

,

781

and remotely activated closing sleeves

726

,

727

, but allowing for carrier fluid

750

recirculation. Once again, each zone of interest

710

,

711

is isolated by packers

720

,

721

,

722

. As with the embodiment shown in

FIG. 4

, there is an inner tubing string

714

, a middle tubing string

716

, and an outer tubing

704

.

FIG. 7

also illustrates crossover ports

740

,

741

at every zone of interest

710

,

711

adjacent to gravel pack ports

724

,

725

and closing sleeves

726

,

727

. Again, the closing sleeves

726

,

727

are operated by remotely controlled actuators

728

,

729

. However, the embodiment shown in

FIG. 7

, rather than having a remotely activated crossover tool that can open and close, has remotely activated inner closing sleeves

790

,

791

exterior to the middle tubing

716

used to open and close the ports

795

,

796

adjacent to the screens

706

,

707

. These inner closing sleeves

790

,

791

are actuated by, for example, remotely controlled actuators

792

,

793

.

As with the embodiment shown in

FIG. 5

, the invention illustrated in

FIG. 7

does not require any manipulation of the work string within the outer tubing

704

. The packers

720

,

721

are set either simultaneously or sequentially by the same method described above for the embodiment illustrated in FIG.

5

. The isolation packers

720

,

721

can also be set sequentially starting at the top of the assembly by closing the iris plug

780

immediately below the crossover port

740

collocated with the gravel pack port

724

in question and closing the said port

724

(as illustrated), thus isolating the fluid between the seal

730

and the packer

720

. The process is then repeated for each additional zone.

The gravel pack is performed by starting at the bottom of the assembly and closing the lower iris plug

781

while opening all up-well plugs

780

. The closing sleeve on the outer tubing

727

is opened as well as the inner closing sleeve

791

on the middle tubing

716

. All other inner closing sleeves

790

are closed. Fluid flow

750

is now routed through the crossover

741

, out the open gravel pack port

725

(since the seals

731

require such flow), and into the wellbore annulus

702

. If return circulation is being allowed, and the carrier fluid is filtered through the screen

707

and enters the open port

796

in the middle tubing

716

. The annulus between the inner tubing

714

, and the middle tubing may be permanently plugged below the bottommost zone

710

,

711

, or alternatively, an additional remotely activated plug or circulation valve could be placed below the port

786

on the middle tubing

716

and closed to redirect the carrier fluid upward through the annulus between the inner tubing

714

and the middle tubing

716

. The carrier fluid may then flow into the annulus between the inner tubing

714

and the middle tubing

716

and circulate through to a port

738

above the inner packer.

Once the gravel pack job is completed on the lowest zone

711

, the lower gravel pack port

725

is closed with the closing sleeve

727

, the next iris valve

781

is closed, and the lower closing sleeve

791

is repositioned to close the lowest port

796

. The two sleeves

726

,

790

in the next zone of interest

710

are opened in order to repeat the gravel pack step disclosed above. After all the zones

710

,

711

of interest have been completed, the work string is removed and appropriate production tubing is run into the well.

The embodiments illustrated by

FIGS. 4

,

5

, and

7

are shown operating in two zones of interest. However, it is understood that the components of each embodiment can be repeated in order to utilize this invention in multi-zone completions having any number of zones of interest. Further, it is understood that the individual elements of each embodiment, such as remotely activated crossover tools, closing sleeves, and plug valves can be combined in numerous individual embodiments consistent with the overall goals of this invention.

Although preferred embodiments of the present invention have been described in the foregoing description and illustrated in the accompanying drawings, it will be understood that the invention is not limited to the embodiments disclosed, but is capable of numerous rearrangements, modifications, and substitutions of steps without departing from the spirit of the invention. Accordingly, the present invention is intended to encompass such rearrangements, modifications, and substitutions of steps as fall within the scope of the appended claims.

Number	Name	Date	Kind
3262499	Fleming	Jul 1966	A
3741300	Wolff et al.	Jun 1973	A
4105069	Baker	Aug 1978	A
4401158	Spencer et al.	Aug 1983	A
4856591	Donovan et al.	Aug 1989	A
5577559	Voll et al.	Nov 1996	A
5896928	Coon	Apr 1999	A
5921318	Ross	Jul 1999	A
5975205	Carisella	Nov 1999	A
6202742	Echols	Mar 2001	B1
6230803	Morton et al.	May 2001	B1
6298916	Tibbles et al.	Oct 2001	B1
6311772	Myhre et al.	Nov 2001	B1

Remotely operated multi-zone packing system

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (13)

Non-Patent Literature Citations (2)

Entry
Haliburton Energy Services, Inc., Sand Control Products and Services, 1997, pp. 4-6 and 4-7, U.S.A.
Petroleum Engineering Services, Inc., Surface Controlled Reservoir Analysis & Management System, Scotland, U.K. (brochure publication date unknown).