The present disclosure relates to damping pressure pulses in a well system.
Treatment fluids can be injected into a subterranean formation for a variety of purposes, including to facilitate production of fluid resources from the formation. For example, in a hydraulic fracturing treatment, fracture treatment fluids are pumped into the formation through a wellbore at high pressure and high rate to cause the formation around the wellbore to fracture. The resulting fracture efficiently conducts fluids from a large area of the formation back to the wellbore. In an acid treatment, for example, an acid treatment fluid can be pumped through a wellbore into the formation, in connection with or apart from a fracturing treatment, to increase or restore the permeability of rock matrix. In a heated fluid treatment, heated treatment fluids, such as steam, can be pumped through a wellbore into the formation to reduce the viscosity of fluid resources in the formation, so that the resources can more freely flow into the wellbore and to the surface. In sweep injection treatment, sweep treatment fluids may be injected into one or more injection wellbores to drive fluid resources in the formation towards other wellbores. Other examples of treatments and treatment fluids exist.
In addition to or apart from use of treatment fluids, energy can be emitted in the subterranean zone via a downhole pressure pulse generator for a variety of purposes, including for fracturing or for facilitating fracturing the formation, and for stimulating the rock matrix of the formation to facilitate communication of treatment or other fluids through the formation. Other examples exist, and often the pressure pulse is applied in connection with another well treatment. The propagating energy is often quite strong, for example, creating pulses orders of magnitude of the pressure in the well system. Containing this magnitude of energy waves prevents damage of the downhole and surface well system and equipment and helps to concentrate the energy waves to the subterranean formation.
The well system 100 includes a working string 104 configured to reside in the wellbore 102. The working string 104 terminates above the surface 140. The working string 104 includes a tubular conduit of jointed and/or coiled tubing configured to transfer materials into and/or out of the wellbore 102. For example, the working string 104 can communicate fluid 108 into or through a portion of the wellbore 102. In the present example, the fluid 108 is a treatment fluid for a fracturing treatment, an acidizing treatment, a water flood treatment, a steam injection treatment (including cyclical steam injection treatments, i.e., huff and puff, and steam assisted gravity drainage treatments, i.e., SAGD), or another treatment. However, in other instances, the fluid 108 can be reservoir fluids, drilling mud, completion fluid, or another fluid in the wellbore. The working string 104 can be in fluid communication with a treatment fluid supply source. Example fluid supply sources include a steam generator, a surface compressor, a boiler, and/or a pressurized tank. In other instances, the well system 100 can be provided without the working string 104. For example, well tools can be communicated in an out of the wellbore 102 via a wire (wireline, slickline, e-line, etc.).
The casing can include perforations 116 in a subterranean region or zone, and the treatment fluid 108 can flow into a treatment zone 118 through the perforations 116. In instances where the wellbore 102 is left open in an “open hole configuration” coinciding with the treatment zone 118, the treatment fluid 108 can flow through the open hole wall of the wellbore 102. Additionally, resources (e.g., oil, gas, and/or others) and other materials (e.g., sand, water, and/or others) may be extracted from the zone of interest 118. The casing 106 or the working string 104 can include a number of other systems and tools not illustrated in the figures.
The well system includes one or more downhole type pressure pulse generators 120. A pressure pulse generator 120, also known as an acoustic pulse generator, is a device configured to create propagating energy waves via a pressure pulse. The pressure pulse generator 120 creates one or more pressure pulses of specified characteristics (e.g., frequency, magnitude, duration and/or other characteristics). The characteristics of the pressure pulses can be distinct from the ambient pressure waves in the wellbore environment, such as ambient pressure caused by operating equipment in the wellbore (of the type not intended for producing pressure/acoustic pulses). For example, the pressure pulse generator 120 can create pressure pulses with many times greater magnitude than any ambient pressure waves in the wellbore 102. The pressure pulse generator 120 can generate the pressure pulses into the fluids in the wellbore, including the treatment fluid 108 or other fluids or combinations of fluids. In certain instances, the pressure pulse is a reservoir treatment pressure pulse with specified characteristics for treating the treatment zone 118 or for augmenting another treatment of the treatment zone 118. In certain instances, the pressure pulse generator 120 creates energy waves with a specified frequency or frequencies of 1-20 Hz, 1-40 Hz or other. The pressure pulse generator 120 can be located at any position along the length of the wellbore, but in most instances it will be located in, adjacent or near the treatment zone 118. The pressure pulse generator 120 can be affixed to the string 104 or the casing 106, or supported on wire. The pressure pulse generator 120 can generate energy waves via several possible manners, including acoustic, via combustion or pyrotechnic manners. In certain instances, the pressure pulse generator 120 can create a pressure pulse of approximately ten times greater than a pressure of the treatment fluid 108.
The pressure pulse generator 120 is designed to create lateral energy waves 114, i.e., to emanate generally radially from the wellbore, to excite the matrix in the treatment zone 118. The lateral energy waves 114 generated by the pressure pulse can be useful for several purposes. For example, a water flood fluid can be pumped into the wellbore 102 and the pressure pulse can excite the matrix to improve water flow in the treatment zone 118, such as by improving the uniform distribution of the water through the zone 118. As another example, the matrix can be excited by a pressure pulse while an acid is pumped into the wellbore 102, which can improve acidization of the matrix. As another example, the pressure pulse generator 120 can activate while a fracturing fluid is present in and/or being pumped into the wellbore 102. The pressure pulse can create further fracturing of the treatment zone to improve permeability and flow.
In a typical implementation, treatment fluid 108 is continuously pumped into the wellbore 102, for example via the working string 104 and/or the annulus between the working string 104 and wellbore 102 wall, while the pressure pulse generator 120 is activated. A portion of the energy waves created by the pressure pulse generator 120 tend to propagate axially through the treatment fluid 108 towards the surface 140 and toward the bottom of the wellbore 102. In some instances, these energy waves 112 can damage the string 104, the casing 106, associated equipment or other components inside the wellbore 102 or at the surface 140.
A damper 110 can be implemented within the wellbore 102 to damp transmission of a pressure pulse through the fluid in the wellbore while allowing fluid flow through the wellbore during the pressure pulse. The damper 110 is a system of one or more techniques or components that can dissipate the energy waves 112 of the pressure pulse as they propagate through the fluids in the wellbore 102. The damper 110 can be positioned above and/or below the pressure pulse generator 120, for example, to damp transmission of the pressure pulse toward the surface 140 (when above) or deeper into the wellbore 102 (when below). The damper 110 provides an additional degree of damping beyond what is normally present in the wellbore environment. The damper 110 can be configured to provide a specified degree of damping. In some instances, the pressure pulse is of a magnitude that would, if undamped, cause damage to equipment in the wellbore 102, at the surface 140 or otherwise associated with the well 100. The degree of damping can be specified to prevent damage of any equipment associated with the well 100 due to the pressure pulse generated by the generator 120. The damper 110 is configured to allow fluid flow through the wellbore between the surface 140 and a location adjacent the pressure pulse generator 120, and in some instances allow fluid flow past the damper 110, while the damper is damping the pressure pulse. In certain instances, the damper 110 can seal flow in one direction while allowing flow in the opposing direction. However, the damper 110 need not seal against flow (in one or both directions) while damping. As such, the damper 110 enables maintaining fluid flow and pressure within the wellbore 102 during a well treatment. Thus, in an instance where treatment fluid 108 is being supplied to a subterranean zone 122 while the pressure pulse is being propagated into the subterranean zone 122, flow of the treatment fluid can continue uninterrupted. In other words, the damper 110 can operate during a fracturing treatment, during an acid treatment, during a water flood, during a steam injection and/or during other types of treatment, without necessitating the treatment be paused during the pressure pulse. However, the concepts herein are equally applicable to instances where the flow of treatment fluid is paused. The damper 110 can reduce the possibility of wellbore and equipment damage from the energy waves 112 while still maintaining appreciable pressure or flow within the wellbore 102. The damper system 110 can be located in the string tubing 104 (or on wire) or in the annulus between the string 104 and the casing 106 or in both.
The sloped shape of the conical baffles 130 can be oriented to deflect and dissipate the energy waves 112 created by the pressure pulse generator 120 while still allowing treatment fluid 108 to flow downhole and maintain pressure within the wellbore 102. For example, when provided on the casing 106, the baffles 130 have their larger diameter oriented uphole and their smaller diameter oriented downhole. When provided on the working string 104, the baffles 130 have their larger diameter oriented downhole and their smaller diameter oriented uphole. The conical baffles 130 can have apertures, slots, valves or other openings that permit fluid flow in the downhole direction. In certain instances, the valves can be check valves oriented to permit fluid flow in the downhole direction and block fluid flow (and the energy waves) in the uphole direction. In certain instances, the conical baffles 130 can include a conical rigid main body 126 and a flexible lip 128 that flexes to permit fluid flow past the lip 128 in the downhole direction. The rigid body 126 could be composed of a rigid material such as steel or some other material or combination of materials. The rigid body 126 may be solid or may have apertures or slots. The flexible lip 128 is located around a perimeter of the rigid body 126 and can form a flexible seal contacting the working string 104, the wellbore casing 106, or another component of the well system. For example, in
The above damping systems (gas slug, conical baffles, flow reduction, damping with the formation) can be used individually or in combination. All three example damping systems could be used on a single well system, or a subset could be used. For example, a gas slug could be injected into a wellbore in which conical baffles are installed. Additionally, flow reduction could be implemented along with a gas slug, or flow reduction could be implemented in a wellbore in which conical baffles are installed. Combining damping systems can be more effective in reducing unwanted pressure than using a single damping system.
A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made. Accordingly, other implementations are within the scope of the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US13/56484 | 8/23/2013 | WO | 00 |