BR112015011564B1 - SYSTEM AND METHOD FOR DELAYED ACTIVATION USING A DESTRUCTIBLE IMPEDANCE DEVICE - Google Patents

Abstract

1/1 SUMMARY SYSTEM AND METHOD FOR DELAYED ACTIVATION USING A DESTRUCTIBLE IMPEDANCE DEVICE. This descriptive report refers to a system and method for delayed actuation employing a destructible impedance device. In one embodiment, a delayed actuation system may comprise a base tube incorporating a first portion of an orifice, a sliding sleeve around the base tube, the sliding sleeve comprising a second portion of said orifice, in addition to said sliding sleeve being maneuvered to a first position, said first portion of said hole being located at least partially over said second portion of said hole, and to a second position, at a distance away from said second position. Furthermore, the delayed actuation system may comprise of a biasing device propelling the biasing sleeve towards the second position, and a destructible impedance device at least partially on the side of said hole, the destructible impedance device preventing the sleeve from slide leave first position.

Description

FUNDAMENTALS

[0001] The present report relates to a fracture system and method for the acquisition of oil and gas.

[0002] The demand for oil and natural gas has grown significantly over the years generating low productivity reservoirs of oil and gas somewhat economically viable, with hydraulic fracturing becoming an important part of these energy productions throughout the planet. For several decades, different technologies have been used to improve methods aimed at the production of resources from gas wells and oil pipelines. Extensive horizontal wellbore holes with multiple fractures comprise a process commonly used to enhance the extraction of oil and gas from wells. This process begins after a well has been drilled and the well hole has been completed. Multi-stage hydraulic fracturing comprises a method involving pumping large amounts of pressurized water or gel, a propionate and/or other chemicals into the wellbore to create multiple discrete fractures in the reservoir along the wellbore. pit.

[0003] One of the technologically advanced methods currently being employed is the simultaneous fracture through propionates, performing up to thirty fractures in a single pumping operation. This method involves the use of propionate to prevent fracture closure. However, this practice can, in general, lead to an uneven distribution of propionate between fractures, which will reduce the efficiency of the fracture system. It is believed that this practice can also cause the fractures to spread in areas that are outside the reservoir in question. Thus, such a method can become inefficient and unsafe.

[0004] Additionally, propionate fracture involves, in general, multiple steps and makes use of several tools that will be executed successively. Such a practice, which will enable a uniform distribution of propionate among the invoices, highly depends on sets of plugs between the fracture stages or on the use of fracture spheres of increased sizes. In these methods, the plugs are either adjusted after the drilling and pumping of each fracture has taken place, or when the fracture balls are lowered from the surface to the successive opening of fracture valves arranged along the well. For each stage, balls of different diameters are lowered into the well corresponding to a specific frac valve seat. At this height in the well, the ball will no longer go through it due to a decrease in the diameter of the well. Once the ball is properly positioned, fracture can occur. After fracture, the plugs must be drilled and the spheres retrieved. From each stage of fracture incorporating the set of plugs, a lot of time and energy is consumed in excavating the hole between the stage part and drilling with the plugs. In addition, land-based garrisons are generally rented on a daily basis, so any delays can significantly increase the cost of operation. Furthermore, only about 12 different fracture stages are possible with the ball method before there is a restriction in the flow area due to the small diameter of the sphere making it difficult to make the fracture with large pressure losses.

[0005] Therefore, it must be feasible to have an improved system and method for fracturing oil and gas wells.

SUMMARY

[0006] The present report is related to a system and method for delayed activation with the employment of a destructible impedance device. In one embodiment, a delay drive system may comprise a base tube containing a first portion of an orifice, a sliding sleeve around the base tube, with the sliding sleeve containing a second portion of said orifice, in addition to said sleeve The slide is maneuverable to the first position, the first portion of said hole being accommodated at least partially over said second portion of said hole, a second position spaced apart from said second position. Furthermore, the delayed actuation system may incorporate a tilting device biasing the sliding sleeve towards the second position and a destructible impedance device at least partially on the side of said hole, the destructible impedance device preventing the sliding sleeve from leaving the first position.

[0007] Additionally, there is a description of a delayed start method. The method may comprise connecting a base tube within a chain of tubes, the base tube comprising a first portion of an orifice, with the application of a force close to the sliding sleeve using an inclination device, the force configured to actuating the sliding glove from a first position to a second position, the sliding glove comprising a second portion of a hole, the sliding glove positioned in said first position, the second position of the hole being accommodated at least partially over the first portion of the hole, said second portion distanced from the second position, and preventing the slide sleeve from leaving the first position by employing a destructible impedance device.

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] Figure 1A illustrates a side view of a base tube.

[0009] Figure 1B illustrates a front view of a base tube.

[0010] Figure 1C illustrates a cross section of a base tube.

[0011] Figure 2A illustrates a sliding glove.

[0012] Figure 2B illustrates a front view of a sliding glove.

[0013] Figure 2C illustrates a cross-sectional view of a sliding glove.

[0014] Figure 2D illustrates a cross-sectional view of a sliding sleeve that further comprises a fixed sleeve, and an actuator.

[0015] Figure 3A illustrates a peripheral view of an outer ring.

[0016] Figure 3B illustrates a front view of an outer ring.

[0017] Figure 4A illustrates a valve housing.

[0018] Figure 4B illustrates a fracture inlet of a valve housing.

[0019] Figure 4C illustrates a production slot of a valve housing.

[0020] Figure 5 illustrates a fracture valve in a fractured condition.

[0021] Figure 6 illustrates an example of an impedance device in action opposite the actuator, in a mode where the impedance device consists of a tension device such as a cord.

[0022] Figure 7 illustrates an example of an impedance device in action opposite the actuator, in a mode where the impedance device consists of a compression device such as a bar.

[0023] Figure 8 illustrates a fracture valve in a production condition. DETAILED DESCRIPTION

[0024] There is a description in this report of a system and method for controlling the flow in a chain of tubes using a reed valve. The following description is presented to enable any person skilled in the art to make and make use of the invention as claimed and being made available within the context of the particular examples discussed below, with variations thereof being readily apparent to those skilled in the art. In the interest of clarity, not all characteristics of a current implementation are described in this report. It should be appreciated that in developing any type of current implementation (such as the development of any such project), design decisions must be made to achieve the designers' specific objectives (eg, compliance with system and business-related constraints ), and that these goals will vary from one implementation to another. It should also be appreciated that such a development effort can be complex and time-consuming, however, and should be viewed as a routine to the field's technical experts as to the appropriate technique incorporating the benefit of this descriptive report. Consequently, the claims attached hereto are not intended to be limited to the described modalities, it being understood, however, that the scope of greatest possible scope is consistent with the principles and characteristics described herein.

[0025] Figure 1A illustrates a side view of a base tube 100. The base tube 100 can be connected as a portion of a string of tubes. In one embodiment, the base tube 100 may be of a cylindrical material which may comprise of differentiated wall openings and/or slits. The wall openings of base tube 100 may comprise insertion inlet 101, fracture inlet 102, and/or production inlet 103. Insertion inlet 101 may be formed from one or more small openings in base tube 100. fracture entry 102 can also be made from one or more openings. Furthermore, the production inlet 103 may comprise a plurality of openings in the base tube 100.

[0026] Figure 1B illustrates a front view of the base tube 100, further comprising a chamber 104. The chamber 104 may be a cylindrical opening or a space created in the inner part of the base tube 100. For this purpose, the chamber 104 may have a opening that may allow the passage of fracture fluid or hydrocarbons. Figure 1C illustrates a cross-sectional view of a base tube 100. Each wall opening discussed above may be circularly positioned around the base tube 100.

[0027] Figure 2A illustrates a sliding sleeve 200 connected with the fixed sleeve 205 by means of an actuator 206, and aligned with an outer ring 207. In one embodiment, the sliding sleeve 200 may comprise of a cylindrical tube comprising inlet fracture port 102. Thus, fracture inlet 102 may have a first portion within base tube 100 and a second portion within sliding sleeve 200. Figure 2B illustrates a front view of a sliding sleeve 200 further comprising a outer chamber 201. In one embodiment, outer chamber 201 may contain a larger opening than chamber 104. For this purpose, outer chamber 201 may be large enough to accommodate base tube 100.

[0028] Figure 2C illustrates a cross-sectional view of a sliding glove 200. The sliding glove 200 may comprise a first glove 202 and a second glove 203. The first glove 202 and the second glove 203 can be secured through one or more curved plates 204, with the spaces between each curved plate 204 defining a portion of the fracture inlet 102. The inner surface of the first sleeve 202 may have a neck void, or any other void within the inner surface. The void space may extend radially around the complete inside diameter of the base tube 100, partially around the inside diameter, or locally. If it is completely around the inner diameter, the ends of the inner surface may have a smaller diameter than the empty space.

[0029] Figure 2D illustrates a cross-sectional view of a slide sleeve 200 further comprising slide sleeve 205, and actuator 206. In one embodiment, the actuator 206 may consist of a tilting device. In such an embodiment, the tilting device may comprise a spring. In another modality, the actuator 206 can be bidirectional and/or motorized. In one embodiment, the second sleeve 203 of the slide sleeve 200 can be secured together with the fixed sleeve 205 using actuator 206. In one embodiment, the slide sleeve 200 can be biased toward the fixed sleeve 205 by compressing or otherwise loading the 206 actuator with potential energy. Finally, the actuator 206 can be released or otherwise urged to drive the sliding sleeve 200 beyond the fixed sleeve 205.

[0030] Figure 3A illustrates a peripheral view of the outer ring 207. In one embodiment, the outer ring 207 may consist of a solid cylindrical tube forming an annular chamber 301, as seen in Figure 3B. In one embodiment, the outer ring 207 may include embedded solid material forming a cylindrical shape. The annular chamber 301 may consist of the space formed on the inside of the outer ring 207. In addition, the annular chamber 301 may be wide enough to slide over the base tube 100.

[0031] Figure 4A illustrates a valve housing 400. In one embodiment, the valve housing 400 may consist of cylindrical material, which may comprise fracture inlet 102, and production inlet 103. In one embodiment, the inlet of fracture 102 may comprise a plurality of openings circularly positioned around valve housing 400, as seen in Figure 4B. In addition, production inlet 103 may consist of one or more openings around valve housing 400, as seen in Figure 4C.

[0032] Figure 5 illustrates a fracture valve 500 in fracture mode. In one embodiment, frac valve 500 may comprise base tube 100, slide sleeve 200, outer ring 207, and/or valve housing 400. In such embodiment, base tube 100 may consist of the innermost layer of the reed valve 500. An intermediate layer around base tube 100 may comprise outer ring 207 secured to base tube 100 and slide sleeve 200, with fixed sleeve 205 being secured to base tube 100. 500 may comprise valve housing 400 in the form of an outer layer. The valve housing 400 can, in one embodiment, become connected to the base ring 108, the outer ring 207 and the fixed sleeve 205. In a fractured position, the fracture inlet 102 can be aligned and opened, due to the positioning in relation to the base tube 100 and the sliding sleeve 200.

[0033] Fracture valve 500 may further comprise a fracture ball 501, and one or more stop ball 502. In one embodiment, stop ball 502 can accommodate insertion inlet 101. Under a condition of fracturing, actuator 206 may present itself in a closed condition, pushing stop ball 502 partially into chamber 104. In such a condition, fracture ball 501 can be released from the surface and into the well. Fracture ball 501 may be retained with insertion inlet 101 via any of the prominent stop balls 502 while fracture valve 500 is in a fracture mode. For this purpose, the prominent portion of the interruption ball 502 can retain the fracture ball 501. In this condition, the fracture ball 102 will be open, allowing the flow of the propionate from the chamber 104 through the fracture inlet 102 and converging on formation, thus giving conditions the occurrence of fracture.

[0034] Figure 6 illustrates an example of an impedance device in contraposition to the actuator 206, in a mode where the impedance device consists of a tension device such as a cord 601. The cord 601 can connect the sliding sleeve 200 to the base tube 100. While intact, the lanyard 601 can prevent the release of the actuator 206. Since the tilt device tries to urge or push the tilt device 200 in one direction, it also applies tension to the lanyard 601. lanyard 601 prevents actuation of actuator 206. Once the lanyard is broken, actuator 206 may drive slide sleeve 200.

[0035] Figure 7 illustrates a second example of an impedance device against the actuator 206, in a mode where the impedance device comprises a compression device, such as a bar 701. While intact, the bar 701 may prevent the release of actuator 206. Once actuator 206 attempts to drive or urge sliding sleeve 200 in one direction, it applies a tension force to bar 701. Bar 701 can be held in position in a variety of ways ,. In one embodiment, bar 701 can be connected to base tube 100 and/or slide sleeve 200 and base tube 100 can retain the positioning of bar 700. In another embodiment, bar 701 can fit between receptacles attached to the sleeve slide 200 and/or base tube 100.

[0036] In one embodiment, the impedance device may be destructible. A destructible impedance device is that device that meets certain conditions. One method of breaking impedance devices is to propel a corrosive material reactive with the impedance device through the fracture inlet 102, with impedance deteriorating until the actuator 206 can overcome this impedance. This method can work in embodiments where the impedance device consists of a corrosive material (such as animal hair in the case of a 601 cord). The corrosive material may comprise a chemical such as hydrochloric acid. If the impedance device incorporates corrosive material, then other methods can be employed to break it. If the impedance device is made of thin steel or some other type of material, it can predictably fail after a lot of fluid passes around it, with erosion over time. Another method of breaking by the impedance device is by pushing a fluid containing particulates such as sand or stones through the fracture inlet 102, in a modality in which the impedance device consists of a material capable of erosion, such as soft stone, or mixed sand, formed and hardened with weak epoxy. Another method of breaking impedance devices consists of propelling a large object such as a sphere into the hole and through the fracture inlet 102. The systems and methods described in this report with respect to delayed actuation employing a device impedance, may function similarly for holes that do not comprise the fracture inlet 102.

[0037] Figure 8 illustrates the fracture valve 500 in production mode. As slide sleeve 200 is pushed towards outer ring 207 by actuator 206, fracture port 102 may close and production port 103 may open. Concomitantly, frac ball 501 can drive stop balls 502 back to the inner end of first sleeve 202 which can further enable frac ball 501 to slide through base tube 100 to another frac valve 500. once production input 103 is opened, oil and gas extraction can begin. In one embodiment, the production inlets may have a gauging valve to allow further fracture to proceed downstream without having to push the fluid through the production inlet.

[0038] Several changes in the details of the illustrated operating methods are possible without deviating from the scope of the following claims table. Some of the modalities may combine the activities described in this report as comprising of separate steps. Similarly, one or more of the steps described may be omitted, depending on the specific operating environment the method is implemented. It should be understood that the above description is intended to be illustrative rather than restrictive. For example, the modalities described above can be combined with each other. Many other modalities will become evident from the observation of the specialist in the field upon a review of the above description. Therefore, the scope of the invention is to be determined by reference to the appended table of claims, together with the full scope of qualified equivalences of such claims. In the attached claims table, words such as “including” and “in which” are used within the equivalence of standard English to the respective words “comprising” and “wherein”.

Claims (10)

1. Delayed drive system, characterized in that it comprises a base tube comprising a first portion of an orifice; and a sliding sleeve around said base tube, with said sliding sleeve comprising a second portion of said hole, said sliding sleeve further being positioned in a first position, wherein said first position of said hole is at least partially located. on said second portion of said hole; and a second position, at a distance away from said first position, the biasing device propelling said sliding sleeve towards said second position; and a destructible impedance device at least partially within said first portion of said orifice, and at least partially within said second portion of said orifice, with the destructible impedance device preventing said sliding sleeve from coming out of said first. position, wherein said destructible impedance device is a strand, said destructible strand applying a tensile force on said strand. 2. Delayed drive system, according to claim 1, characterized in that said impedance device is dissolvable by a chemical. 3. Delayed drive system according to claim 2, characterized in that said chemical is hydrochloric acid. 4. Delayed drive system according to claim 1, characterized in that said impedance device is corroded by particulates contained in a fluid stream passing through said orifice. 5. Delayed actuation method, characterized in that it comprises connecting a base tube inside a chain of tubes, said base tube comprising a first portion of an orifice; applying a force near a sliding glove using a biasing device, said force configured to drive said sliding glove from a first position to a second position, said sliding glove comprising a second portion of said hole, with the said sliding sleeve positionable in said first position, said second portion of said hole being at least partially located over said first portion of said hole; and said second position at a distance away from said first position; preventing said sliding sleeve from leaving said first position by employing a destructible impedance device, said destructible impedance device at least partially within the first portion of said hole, and at least partially within said second portion of said hole , wherein said destructible impedance device is a strand, said destructible strand in part applying a tensile force on said strand. 6. Method according to claim 5, characterized in that said impedance device is destructible by a chemical. 7. Method according to claim 6, characterized in that it further comprises the step of decanting the hydrochloric acid through said hole to break said impedance device. 8. Method according to claim 5, characterized in that said impedance device is destructible by erosion. 9. The method of claim 8, further comprising the step of sending a fluid comprising particulates through said orifice for erosion of said impedance device. 10. Method according to claim 5, characterized in that it further comprises propelling an object through said hole to break said impedance device.

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