This invention relates generally to the field of hydraulic fracturing systems, and more particularly, but not by way of limitation, to a plug for controlling access to selective zones within a well during a hydraulic fracturing operation.
Hydrocarbons, such as oil and gas, may be recovered from various types of subsurface geological formations. The oil and gas is accessed through a well which is typically drilled from the surface to the producing formation. In many wells, hydraulic fracturing is used to promote the production of oil and gas from the formation. A process known as plug and perforation is used to isolate and independently stimulate specific zones within the well.
When the well has been drilled to the desired depth, a steel casing is typically installed and cemented within the wellbore to prevent the sides of the wellbore from collapsing and to control the flow of fluids from the formation into the wellbore. Once the casing is cemented in place, a section of the wellbore can be perforated to provide a path from the formation to the wellbore through the cement and casing. In most cases, explosive charges or high pressure fluids are used to perforate the casing and cement. Once the casing has been perforated, the adjacent and nearby formation can be stimulated through hydraulic fracturing by injecting high pressure fluid and proppant is injected into the formation to open and suspend small cracks in the formation. This generally improves the permeability of the producing formation near the well to increase the flow of hydrocarbons into the well.
In wells that are drilled through multiple production zones, it may be desirable to sequentially stimulate the zones by conducting multiple hydraulic fracturing operations. Plugs or other zone isolation devices are used to control which zones are stimulated by blocking the flow of pressurized fracturing fluid to lower portions of the wellbore. Multiple plugs can be deployed and retrieved to carry out a strategic sequence of hydraulic fracturing.
Several types of plugs have been used in the past. In some cases, the plug is a simple blocking device that must be removed or destroyed with a drill to permit flow of wellbore fluids through the plug. In other cases, the plug is provided with a controllable valve mechanism that can be closed to prevent flow through the plug during a stimulation exercise and opened to permit flow during the production phase of the hydrocarbon recovery effort. A “ball drop plug” utilizes a ball which is dropped into the wellbore and caught by the plug to switch the plug from an open state to a closed state in which flow from the surface is prohibited from passing through the plug. Although widely adopted, conventional ball drop plugs tend to be slow to install and operate and it can be difficult to confirm that the dropped ball has placed the appropriate plug in a closed position.
In contrast to a ball drop plug, a ball-in-place plug is set into the wellbore with a ball already on the seat of the plug while it is run in hole. This speeds up the frac process because the operator does not have to pump a ball down from the surface to close the seat of a ball drop plug. Although ball-in-place plugs are generally effective at isolating lower zones from pressurized fluid above the plug during a hydraulic fracturing operation, the ball-in-place plugs do not permit flow through the plug from the surface for pump down or other operations. If, for example, there are issues with the perforation process, the inability to flow fluid from the surface through the ball-in-place plug can cause costly delays. In these instances it can be necessary to drill out and replace the entire ball-in-place plug.
There is, therefore, a need for an improved plug which saves production time by allowing fluid to flow through the plug and which does not require a ball drop step to set the plug. It is to these and other objectives that the present invention is directed.
In exemplary embodiments, the plug and perforation system disclosed herein includes a setting tool that is connected to a plug, a perforation gun, and a wireline. The wireline lowers the perforation gun, setting tool and plug into a wellbore. The setting tool then sets the plug into the wellbore at the desired location. The plug includes an anchoring subassembly, a sealing element device, and a flow control subassembly. The anchoring subassembly sets the plug into the wellbore and the sealing element device seals the plug within the wellbore. The flow control subassembly of the plug controls the flow of fluid through the plug and the wellbore. Before the flow control assembly is activated, fluid can flow freely through the plug. Once the flow control assembly has been activated, the plug prevents fluid from flowing through the plug deeper into the wellbore, thereby isolating a wellbore section from other sections of the wellbore. An activated plug can still allow fluid to flow up from the wellbore through the plug. A flow control subassembly can have a threshold which when reached will activate the plug. The plug threshold can be adjusted to respond to different wellbore conditions such as flow rate or plug pressure to activate the plug.
In one embodiment, the present disclosure is directed to a plug configured to isolate formation zones within a wellbore. The plug includes a flow control subassembly configured to control the flow of fluid through the plug and an anchoring subassembly configured to secure the plug in the wellbore. The flow control subassembly includes a central chamber, a ball, and an offset chamber connected to the central chamber. The offset chamber includes a ball release mechanism that is configured to selectively release the ball from the offset chamber into the central chamber.
In another embodiment, the present disclosure is directed to a plug configured to isolate formation zones within a wellbore. The plug includes a flow control subassembly configured to control the flow of fluid through the plug, an anchoring subassembly configured to secure the plug in the wellbore, and a sealing device between the flow control subassembly and the anchoring subassembly. The flow control subassembly includes a central chamber, a ball, and an offset chamber connected to the central chamber. The offset chamber includes a ball release mechanism that is configured to selectively release the ball from the offset chamber into the central chamber.
In yet another embodiment, the present disclosure is directed at a ball-in-place plug configured to isolate formation zones within a wellbore, where the ball-in-place plug includes an anchoring subassembly configured to secure the ball-in-place plug in the wellbore and a flow control subassembly configured to control the flow of fluid through the plug. The flow control subassembly is configured to allow bidirectional flow of fluid through the ball-in-place plug before the ball-in-place plug is activated, and wherein the flow control subassembly is configured to permit only unidirectional flow of fluid through the ball-in-place plug after the ball-in-place plug is activated.
In accordance with exemplary embodiments of the present invention,
The plug and perforation system 100 prepares the formation 200 for hydraulic fracturing by perforating the casing 204 and cement 206 using a perforation gun 102 and isolating sections of the wellbore 202 using plugs 104. Using the plug and perforation system 100, sections of the wellbore 202 can be separately perforated. Each perforated section can then be isolated from other sections using one or more plugs 104 so that each perforated section can then be independently hydraulically fractured.
The plug and perforation system 100 includes a setting tool 106 that is connected to the plug 104, a perforation gun 102, and a wireline 108. The plug 104, perforation gun 102 and setting tool 106 can be referred to as the downhole plug assembly 114. The downhole plug assembly 114 is deployed and retrieved using wireline 108. The wireline 108 runs from a wireline van 110 or other wireline deployment machine into the wellbore 202 through a wellhead 112. In some applications, it may be desirable to pump fluid through the wellhead 112 into the wellbore 102 to facilitate the deployment of the downhole plug assembly 114 into the wellbore 102.
As seen in
As depicted in
Turning now to
The anchoring subassembly 120 sets the plug 104 into the casing 204 of the wellbore 202, preventing movement of the plug 104 within the casing. In the present embodiment, the anchoring subassembly 120 is positioned adjacent to the sealing device 118 at the distal end of the plug 104 from the wireline 108 connection. The sealing device 118 seals the plug 104 between the anchoring subassembly 120 and the casing 204, preventing fluid from flowing between the plug 104 and the casing 204. In the present embodiment the sealing device 118 is positioned between the anchoring subassembly 120 and flow control subassembly 116. The flow control subassembly 116 controls the flow of fluid through the plug 104. In the present embodiment the flow control subassembly 116 is positioned adjacent to the sealing device 118 at the proximal end of the plug 104 from the wireline 108 connection.
Turing now to
The setting tool 106 includes a setting body 148, a setting sleeve 150 connected to the setting body 148, and an adapter 152 housed within the setting sleeve 150. A tension rod 156 is threaded into the adapter 152 and extends outward from the setting tool 118. The tension rod 156 is connected to the adapter 152 with a rod nut 154 which is tightened to the adapter 152. A locking sub 158 is connected to the distal end of the tension rod 156.
In
The sealing device 118 includes a seal element 130 which engages the casing 204 to close the gaps between the casing 204 and the plug 104. The sealing device 118 may also include back-ups 132 which support the seal element 130 to prevent extrusion of the seal element 130. In some embodiments the seal element 130 will engage the casing 204 through an electrical signal sent through the wireline 108 or through force applied to the plug 104. In some embodiments the seal element 130 is made of rubber or dissolvable rubber materials. Note that in
Turning now to
The offset chamber 136 is configured to retain the ball 134 until the plug 104 is purposefully activated to permit the plug 104 to prevent the flow of fluid through the plug 104 in a downhole direction. The inner diameter of offset chamber 136 is sized to accommodate the ball 134 in close tolerance. The ball release mechanism 138 is used to retain the ball 134 in the offset chamber 136 until the plug 104 is activated.
In some embodiments, the ball release mechanism 138 is a shearing ring 138a that has a smaller inner diameter that prevents the ball 134 from entering the central chamber 140. If the force applied by the ball 134 to the shearing ring 138a exceeds the threshold rupture force of the shearing ring 138a, the shearing ring 138a will rupture and allow the ball 134 to fall into the central chamber 140. In other embodiments, the ball release mechanism includes one or more shear screws 138b that are configured to fracture when exposed to a design load. The use of shear screws 138b is depicted in the partial cross-sectional view provided by
In other embodiments, the ball release mechanism 138 includes a smaller diameter throat or flange between the offset chamber 136 and the central chamber 140. In this embodiment, the ball 134 can be manufactured from a compliant, deformable material such that the ball 134 can be squeezed through the throat or flange in the offset chamber 136 under sufficient force to allow the ball 134 to enter the central chamber 140.
To improve the reliability of the ball release mechanism 138, the offset chamber 136 may also include a seal 142. In the present embodiment, the seal 142 is incorporated into the walls of the offset chamber 136 to engage the outer surface of the ball 134 while it is held in the offset chamber 136. In this manner, the seal 142 creates a seal between the sides of the offset chamber 136 on either side of the ball 134 to maintain a pressure gradient across the ball 134.
In some embodiments, the ball 134 is provided by an integral extrusion 134 that prevents the ball 134 from spinning within the offset chamber 136. As depicted in
The force required to release the ball 134 from the offset chamber 136 can be generated from a positive force applied by fluid acting on the exterior side of the ball 134, a negative (suction) force applied to the interior side of the ball 134 by fluid passing through the central chamber 140, or a combination of positive and negative forces acting on the ball 134. In the embodiment depicted in
In each embodiment, the ball 134 is released from the offset chamber 136 into the ball chamber 140c, where the ball can move between the upflow seat 146 and the downflow seat 144. The ball 134 has a greater outer diameter than the inner diameter of the downflow seat 144 or the upflow seat 146. If fluid pressure is greater on the uphole side of the plug 104, the ball 134 is pressed against the downflow seat 144 to stop the flow of fluid through the plug 104. If the fluid pressure is greater on the downhole side of the plug 104, e.g., during a production phase, the ball 134 presses against the upflow seat 146 (and fluid flow passes through the offset chamber 136) or the ball 134 returns to the offset chamber 136 (and fluid flow passes out of the plug 104 through the proximal throat 140a).
For example, as shown in
Thus, until the plug 104 is activated, the plug 104 permits the movement of fluids through the central chamber 140 of the plug 104. Once the plug 104 is activated, the plug 104 prevents fluids such as those used in hydraulic fracturing from passing downhole through the plug 104 and deeper into the wellbore 202. Once activated, the plug 104 permits the uphole movement of fluids through the plug 104. In this way, the plug 104 permits bidirectional flow until the plug 104 is activated and the ball 134 is forced out of the offset chamber 136. Once the plug 104 has been activated, the plug 104 acts as a check valve that permits the unidirectional flow of fluids through the plug 104 in the uphole direction while preventing the passage of fluids through the plug 104 in the downhole direction.
Turning back to
It will be noted that although the plug and perforation system 100 is depicted in a horizontal deployment in
In this manner, a novel plug 104 and the incorporation of this novel plug 104 into plug and perforation systems 100 produces the various novel methods and apparatuses disclosed herein for controlling the flow of fluid through a plug 104 to provide a more versatile and efficient solution for isolating fracking zones and allowing fluid flow from a wellbore 202. It is to be understood that even though numerous characteristics and advantages of various embodiments of the present invention have been set forth in the foregoing description, together with details of the structure and functions of various embodiments of the invention, this disclosure is illustrative only, and changes may be made in detail, especially in matters of structure and arrangement of parts within the principles of the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. It will be appreciated by those skilled in the art that the teachings of the present invention can be applied to other systems without departing from the scope and spirit of the present invention.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 63/091,636 filed Oct. 14, 2020 entitled, “Frac Plug and Method of Controlling Fluid Flow in Plug and Perforation Systems,” the disclosure of which is herein incorporated by reference.
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