This invention relates to tool(s), a system and a method for fracturing subterranean formations surrounding oil and/or gas wells.
The present methodology for extended reach fracturing is very time demanding. This makes thus many potential projects and/or wells uneconomical. The existing systems utilize staged perforations, installation of a dedicated straddle system and targeted stimulation of each individual stage in the process. The process is repeated for the number of stages in the well. Each stage then requires multiple installation trips in order to complete the stage, thus causing a single stage to require several days of installation time. This well construction method reduces the effective well diameter for production flow.
One known method is the P.S.I. (Perforate-Stimulate-Isolate) system provided to an operator by an incumbent service provider. Similar methods have been used in coiled tubing applications where the frac is pumped down the annulus. The challenge here is how to use multiple cemented-in frac sleeves on a liner and to perform the frac through a drill pipe into each frac sleeve individually. The drill pipe string is to remain in the well throughout the entire fracturing process. The drill pipe can be a requirement as the frac stages are out of range for coiled tubing operations.
Therefore, an improved way of proppant fracturing of wells is needed. Thus there is a request and/or need for a system which can provide great time savings from the known P.S.I. (Perforate-Stimulate-Isolate) system that has been used in the past 20 years.
The present invention offers an efficient, cost saving proppant fracturing through cemented reservoir sliding sleeves without over-displacing the frac. The frac operation is performed through a threaded pipe in order to enable fracturing in extended reach wells. Well control should be ensured during the deployment and the frac operation. In order to enable proppant retention a sand filtration media can be used as part of the sleeve(s).
Modified frac sleeves can be utilized in order to be run as part of the liner and cemented in place. The modification of each reservoir sliding sleeve includes the inclusion of a dedicated sleeve production position, where the production is filtered in order to retain the proppants in the frac.
Use of dedicated no-go liner ID (inner diameter) restriction(s) in each stage can contribute to efficiently slack off the drill pipe string weight in order to ensure operational robustness during the frac. This can also enable operationally robust frac treatment method(s) and/or option(s) for wells drilled from floating platforms in rough seas.
Inner BHA (bottom hole assembly) can use flexible no-go locator sub, adaptable sleeve shifting tools and a compression activated ported frac sub.
The components that make up the entire system have small or major modifications with respect to existing parts.
The main features of the present invention are given in the attached independent claims. Additional features of the invention are presented in the attached dependent claims.
These and other aspects of the invention are apparent from and will be further elucidated, by way of example(s), with reference to the attached drawings, wherein:
The invention includes all permanently installed reservoir completion equipment run as part of the initial reservoir liner 110.
The use of a jointed service string enables the frac operation also in extended reach applications out of coiled tubing reach.
The frac is pumped through a temporarily installed service string which is sequentially located at each sleeve/injection point. The service string 120 includes devices 300, 7, 8, 9 to manipulate the frac sleeves 2 from closed run-in position, to opened frac position, back to closed position and to open for production position.
The frac sleeve 2 includes a feature which will retain the proppants in the frac eliminating the potential for proppant flow back and frac closure.
A packer (not shown) might still be incorporated a distance above the frac string BHA for well control purposes.
Proppant frac can be run through the inside of a jointed service string.
The system 1, according to the invention and shown in
Use of dedicated no-go liner ID restriction(s) 3 in each stage contributes to efficiently slack off the drill pipe string 120 weight in order to ensure operational robustness during the frac operation. This can also enable operationally robust frac treatment method(s) and/or option(s) for wells 100 drilled for example from floating platforms (not shown) in rough seas.
Inner BHA tool 300 uses a flexible no-go locator sub or device 6, adaptable sleeve shifting tools 7, 8, 9 and a compression activated frac sub 10 with a predetermined number of ports 12.
One embodiment of the invention concerns a BHA tool 300 for single trip through drill pipe proppant fracturing. The BHA tool 300 is at one end adapted to be attached to a string 120. The BHA tool 300 can comprise: i) a ported sub 10, ii) sleeve shifting tools 7, 8, 9, and iii) a locator sub 6. The locator sub 6 can be arranged at the other end of the BHA tool 300. The ported sub 10 can comprise a number of ports 12. The several ports 12 can have opened and closed positions. The sleeve shifting tools 7, 8, 9 can comprise: i) a sleeve closing tool 7; ii) a sleeve fracturing opening tool 8; and iii) a sleeve production opening tool 9. The sleeve closing tool 7 can be adapted to close a certain sleeve 2 cemented in the liner 110 when the BHA tool 300 is moving or going up. The sleeve fracturing opening tool 8 can be adapted to open the sleeve 2 when the BHA tool 300 is moving or going down. The sleeve production opening tool 9 can be adapted to set the sleeve 2 in a production mode.
The ported sub 10 with its ports 12, the sleeve closing tool 7, the sleeve fracturing opening tool 8, the sleeve production opening tool 9 and the locator sub 6 can be arranged on the BHA tool 300 in such a manner that at least one of them would be able to cooperate with at least one of the following: the sleeve 2 in the liner 110, the ID restriction 3 in the liner 110 and the bottom of a wellbore 100.
Another embodiment of the invention teaches a system 1 for single trip through drill pipe proppant fracturing. The system 1 can comprise a predetermined number of sleeves 2 cemented in a liner 110 in a wellbore 100 in a subterranean formation 130 and a predetermined number of ID restrictions 3. In each stage throughout a certain or the entire length of the liner 110, there is a predetermined spacing or distance 4 between the ID restriction 3 and the sleeve 2. The system 1 can further comprise a BHA tool 300 as described above.
Yet another embodiment of the invention relates to a method for single trip through drill pipe proppant fracturing. The method can comprise the following steps:
a) arranging a liner 110 with a predetermined number of sleeves 2 and ID restrictions 3 in a wellbore 100 in a subterranean formation 130, wherein the sleeves 2 and the ID restrictions 3 are being cemented in the liner 110, and wherein, in each stage 1, 2, 3, 4 . . . n, n+1, n+2, n+3, n+4 throughout a certain or the entire length of the liner 110, the ID restriction 3 and the sleeve 2 are arranged with a predetermined spacing or distance 4 between them;
b) clean out run is performed by means of a string 120 having a clean out run string end 121, wherein the inside of the liner 110 is thus being flushed and cleaned;
c) lowering a BHA tool 300 being at one end adapted to be attached to the string 120 and comprising: i) a ported sub 10 with a number of ports 12 having opened and closed positions, ii) sleeve shifting tools 7, 8, 9, and iii) a locator sub 6 being arranged at the other end of the BHA tool 300. The sleeve shifting tools 7, 8, 9 can comprise: i) a sleeve closing tool 7 adapted to close the sleeve 2 when the BHA tool 300 is moving or going up; ii) a sleeve fracturing opening tool 8 adapted to open the sleeve 2 when the BHA tool 300 is moving or going down; and iii) a sleeve production opening tool 9 adapted to set the sleeve 2 in a production mode;
d) the string 120 with the BHA tool 300 is run to the bottom of the wellbore 100 passing through the top end of the liner 110 and all sleeve assemblies 2 and ID restrictions 3 without any interference;
e) the bottom of the wellbore 100 is tagged, and the locator sub 6, the sleeve fracturing opening tool 8 and the sleeve closing tool 7 are activated;
f) the BHA tool 300 is pulled up until the locator sub 6 indicates in lower most ID restriction 3;
g) the string 120 with the BHA tool 300 is pulled such that the sleeve shifting tools 7, 8, 9 are located above the sleeve 2 in the liner 110;
h) the string 120 with the BHA tool 300 is lowered, and the sleeve 2 is opened by the sleeve fracturing opening tool 8;
i) the BHA tool 300 is run in further, and the ID restriction 3 is tagged with the help of the locator sub 6;
j) the weight of the string 120 is slacked off the in order to confirm the frac position, wherein the slack off step opens the ports 12 of the ported sub 10 and the ported sub 10 is located parallel to the opened sleeve 2;
k) the annular 100 is closed, and injection is established, and then frac is pumped until screen out is established;
l) the annular 100 is opened, and a predetermined volume is reverse circulated in order to clean the area outside of the ported 12 sub 10;
m) the BHA tool 300 is pulled up, and the sleeve 2 is closed with the help of the sleeve closing tool 7;
n) the weight of the string 120 is slacked off, and the BHA tool 300 is relocated on the ID restriction 3 with the help of the locator sub 6;
o) all excess proppants from the string 120 are reverse circulated out;
p) the BHA tool 300 is pulled up, and the next ID restriction 3 is located;
q) then steps f)-p) are repeated for a desired number of stages or for all stages 1, 2, 3, 4 . . . n, n+1, n+2, n+3, n+4 throughout the liner 110.
When the desired number of or all stages 1, 2, 3, 4 . . . n, n+1, n+2, n+3, n+4 throughout the liner 110 are fractured and all sleeves 2 are closed, a drop ball 11 can be used in order to deactivate the locator sub 6, the sleeve fracturing opening tool 8 and the sleeve closing tool 7.
The activated sleeve fracturing opening tool 8 is adapted to be able to open all sleeves 2 when going down.
The activated sleeve closing tool 7 is adapted to be able to close any opened sleeve 2 when moving up.
The flexible no-go locator sub or device 6 can for example be built in a similar principle as a shifting tool. Here there can be some sort of “dogs” or “teeth” or “fins”, but not limited only thereto, being able to expand by means of springs and the angle of the “dog” and the profile it should pass through, being designed and shaped, so that the locator sub or device 6 can collapse/can be pushed down when it is pulled in one direction. In the other direction, there are angle(s) making the “dogs” being hit in axial direction, and thus the locator sub or device 6/the “dogs” will not collapse. Alternatively, the locator sub or device 6 can be inflatable.
Here some of the functions of the sleeve 2 manipulating devices/adaptable shifting tools 7, 8, 9 will be explained. The sleeve closing tool 7 is a shift up tool (i.e. it works when moving up), while the fracturing opening tool 8 and the sleeve production opening tool 9 are shift down tools (i.e. they work when moving down). The fracturing opening tool 8 can open a sleeve 2 so that in order to stimulate. Frac can be pumped out of the sleeve 2 and into the formation 130. The sleeve closing tool 7 can close a sleeve 2 so that the volume can be circulated in the well 100. The sleeve production opening tool 9 can open a sleeve 2 for production.
The sleeve 2 can have three positions, where: position 1 (first position) is a closed position; in position 2 (second position) the proppant(s) can be pumped out from the well 100 into the formation 130; and position 3 (third position) is for production mode, where proppant is held back from the formation 130 and into the well 100. This third production position of the sleeve 3 can be screened/filtered. All this can explain why there can be there different shifting tools 7, 8, 9 arranged in the BHA 300.
Below system 1 and method overview and functionality of the preferred embodiment will be described.
1. The liner 110 with the number of frac sleeves 2 is run as required by reservoir conditions (see e.g.
2. Each stage (see 1, 2, 3, 4 . . . n, n+1, n+2, n+3, n+4) consists of a frac sleeve 2 and a slight ID restriction 3 with the same and predetermined spacing or distance 4 between the ID restriction 3 and the sleeve 2.
3. The liner 110 is run as a conventional liner and cemented 200 per normal cementing procedures.
4. A dedicated clean out run is performed by means of a string 120 having a clean out run string end 121, wherein the inside of the liner 110 is thus being flushed and cleaned (see
5. A frac service string BHA tool 300 is picked up and comprises:
The term “slack off” relates to resting the string 120 on a solid base (such as e.g. the bottom of the well 100) or a profile (such as e.g. the indicator sub/ID restriction 3) so that the weight of the string 120 above is transferred to the BHA tool 300. When slacking off a string 120 the weight of the string 120, measured on the surface above, will be lower and can: 1) be used as an indication where the BHA 300 is located, or 2) be functioning a tool downhole.
Additional modifications, alterations and adaptations of the present invention will suggest themselves to those skilled in the art without departing from the scope of the invention as expressed and stated in the following patent claims.
Number | Date | Country | |
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62088101 | Dec 2014 | US |