In oil and gas operations, hydraulic fracturing systems may be used to fracture one or more subterranean formations by conveying pressurized hydraulic fracturing fluid to one or more wellbores traversing the subterranean formation(s), the wellbore(s) each having a wellhead located at the surface termination thereof. These hydraulic fracturing systems require temporary surface lines, valves, and manifolds (collectively referred to as “frac iron”) to deliver the hydraulic fracturing fluid from mixing and pumping equipment to one or more fracturing trees connected to the respective wellhead(s). A fracturing manifold consists of one or more “zipper modules,” which are a collection of flow iron valves, pipes, and components, used to deliver hydraulic fracturing fluid or treatment fluid to multiple fracturing trees. The zipper modules facilitate quick redirection of fracturing fluid and pressure from one well to another, enabling pumping trucks or machinery to run nearly continuously and thereby minimize downtime.
Many hydraulic fracturing systems use conventional frac iron connected to, from, or between: each of the various components of the fracturing manifold, the pressurization manifold and the fracturing manifold, each of the various components of the pressurization manifold, and/or each of the fracturing trees and the fracturing manifold. In particular, zipper modules typically comprise a series of gates, valves, and piping set up to deliver fracturing fluid to the wellhead. Wellheads are situated at different elevations in the field, making it essential for zipper modules to deliver fluids at varying inclinations and declinations and at different angles. For example, one wellhead may be situated at point A, another wellhead may be situated at point B that is X meters east and Y meters above point A, and still another wellhead may be situated at point C that is X′ west and Y′ below point A. To effectively traverse this terrain, conventional setups connect each zipper modules to the wellheads using a complex network of piping and frac iron form the zipper modules to the wellheads. Running multiple pipes from each zipper module to each wellhead creates a multitude of issues at the work site including, but not limited to, excessive setup time and labor costs, limited adjustability, safety risks associated with potential leak points, and decreased pumping efficiency.
The disclosed examples are described in detail below with reference to the accompanying drawing figures listed below. This Summary is provided to illustrate some examples disclosed herein and is not meant to necessarily limit all examples to any configuration or sequence of operations.
One embodiments are directed to a system for establishing a single straight-line fluid path between a fracturing (frac) tree stack and a zipper tree. The system includes: a fluid conduit, a first valve, and a second valve. The fluid conduit, the first valve, and the second valve are coaxially connected to create the single straight-line fluid path along a shared axis between the frac tree and the zipper tree for delivering fluid therebetween.
In some embodiments, the first valve and the second valve each comprise a gate valve.
In some embodiments, the first valve and the second valve each comprise a plug valve.
In some embodiments, the first valve comprises a gate valve and the second valve comprise a plug valve.
In some embodiments, the first valve is manually actuated and the second valve is automatically actuatable.
In some embodiments, the first valve and the second valve are each manually actuatable.
In some embodiments, the first valve and the second valve are each automatically actuatable.
In some embodiments, the first valve or the second valve comprise at least one automatically actuatable valve that may be opened and closed either electrically, electromagnetically, pneumatically, or hydraulically.
In some embodiments, the fluid conduit is connected to an end of the zipper tree, and the first valve is connected to an end of the fluid conduit.
In some embodiments, the fluid conduit is connected between the first valve and the second valve.
In some embodiments, the fluid conduit is connected to a multi-way block that is part of the frac tree.
In some embodiments, the frac tree comprises a multi-way block.
In some embodiments, the multi-way block comprises an internal angled passage that directs fluid received from the single straight-line fluid path to an internal passage of the frac tree directed toward a wellhead.
In some embodiments, the multi-way block comprises at least one member of a group comprising a 3-way, 4-way, or 5-way block with at least one discharge directed to the wellhead.
Other embodiments are directed to a system comprising a fracturing (frac) tree and a zipper module. The system includes two or more valves that are coaxially connected in series between the frac tree and the zipper module. The two or more valves define a single straight fluid path between the zipper module and the frac tree for frac fluid to flow.
In some embodiments, the zipper module defines a first internal fluid passage within the single straight fluid path between the zipper module and the frac tree, the first internal fluid passage being perpendicular to a second internal fluid passage within a second fluid passage within interconnected flow iron of the zipper module.
In some embodiments, the zipper module comprises a zipper tree situated on a base that is adjustable in elevation.
In some embodiments, the zipper module comprises at least rotatable block for receiving the frac fluid.
In some embodiments, the frac fluid is supplied to the at least one rotatable block of the zipper module through a conduit having an internal diameter within a range of 3-7 inches.
Still other embodiments are directed to a system for performing hydraulic fracturing of a plurality of wellheads on a frac site. The system includes at least one zipper tree comprising at least one rotatable block for receiving frac fluid for use in performing they hydraulic fracturing; and an OSL connection comprising at least one gate valve and at least one OSL fluid conduit connected in series and defining a single straight fluid path from the at least one zipper tree to a frac tree.
Notwithstanding any other forms that may fall within the disclosure set forth above in the Summary, embodiments are described below by way of example and with reference to the accompanying drawings that include the following:
Some of the embodiments disclosed herein provide various configurations to deliver a connection between zipper modules receiving hydraulic fracturing fluid (“frac fluid”) to a hydraulic fracturing tree (“frac tree”) for hydraulically fracturing an oil and gas well. The frac trees and zipper modules may be situated out in an oil and gas field across uneven terrain and with differing heights, making the connection of the two conventionally difficult. Examples of frac fluid include, without limitation, water, slickwater, sand, bauxite, or any other fracturing fluid. The connections disclosed herein are created using one or more valves and pipes that form a single straight-line fluid conduit that are coaxially connected along a shared axis to create what is referred to below as a “one straight line” (referred to simply as “OSL”) connection between the frac tree and the manifold module for transporting frac fluid therebetween. As referenced herein, an “OSL connection” refers to a single straight-line fluid path defined within interconnected flow iron connecting a zipper tree and a frac tree.
The OSL connections disclosed herein provide a much more efficient way to connect zipper modules to frac trees. Single connection points are used between zipper modules and frac trees as well (in some embodiments) as between multiple zipper modules to allow flow of frac fluid between the zipper modules themselves. Instead of needing multiple connections between a zipper module and a frac tree, only a single connection is needed. This substantially reduces the complexity of the network of frac iron needed to communicate frac fluid to different frac trees and across varying elevations or directions.
The disclosed OSL connections may be used in fracturing operations or in flowback operations. In flowback operations, the disclosed OSL connections may be connected between the wellhead and a completion or storage tank, using any of the disclosed OSL connections described herein to carry flowback fluid or slurry (e.g., water, sand, frac load recover, proppant, slurry, or the like) away from the wellhead. For the sake of clarify, embodiments disclosed herein refer to OSL connections in fracking operations, i.e., providing frac fluid to the frac tree or wellhead.
The flow iron used to create the OSL connections described herein may include various interconnected flow iron components to create an internal conduit for fracturing fluid to pass form the zipper module to the frac tree. Examples of such flow iron components include pipes, hoses, safety restraints, and any of a number of flow iron valves. Examples of flow iron valves that may be used in the OSL connections mentioned herein include, without limitation, acid valves, API valves, ball valves, butterfly valves, check valves, choke valves, diaphragm valves, gate valves, glove valves, isolation valves, knife gate valves, (pilot-operated or non-pilot operated) pressure relief valves, pinch valves, plug valves, (mechanical and non-pressurized) filing valves, safety relief valves, or the like. Such valves may be manually, electrically, electromagnetically, pneumatically, hydraulically, or otherwise actuated. The above valves and actuation mechanisms, as well equivalents thereof, may be considered “valve means” and “actuation means,” respectively.
While embodiments disclosed herein create OSL connections with specific configurations of gate or plug valves connected to piping, any of the aforementioned valves—and actuation mechanisms—may alternatively be used to create the disclosed OSL connections. Unless otherwise stated herein, the illustrated and depicted embodiments are meant to be non-limiting and non-exhaustive of all embodiments for creating OSL connections. Different valves, piping, and other flow iron may be used to create OSL connections, and such alternative configurations are fully contemplated herein.
Turning to
In operation, hydraulic fracturing fluid (“frac fluid”) contained in the fluid sources 22 is pumped by the various pumps 18a-1 through the manifold assemblies 12-14, which may or more may not pressurize the pumped fluid, to the zipper modules 24a-c. The so-provided frac fluid is, in some embodiments, passed through the iron assembly 26, monitored by the instrument assembly 28, and to the zipper modules 24a-c, where the frac fluid is distributed therebetween. For example, as depicted in
The zipper modules 24a-c represent a vertical structure of flow iron used to elevate frac fluid from the iron assembly 26 to an OSL connection 26a-c. The wellheads 20a-c represent frac trees (or Christmas trees) for receiving the frac fluid from the zipper modules 24a-c, via the OSL connections 26a-c, and supplying the frac fluid to various oil and gas wells.
In some embodiments, OSL connections 26a-c discussed in more detail below are used to provide straight-line fluid pathways between the zipper modules 24c-a and the wellheads 20c-a, respectively. For example, OSL connection 26a provides fluid communication of frac fluid between zipper module 24c and wellhead 20c; OSL connection 26b provides fluid communication of frac fluid between zipper module 24b and wellhead 20b; and OSL connection 26c provides fluid communication of frac fluid between zipper modules 24a and 20a. This depicted setup may be extended to provide any number of interconnected zipper modules 24 to each other and also to wellheads 20 via OSL connections 26.
The wellheads 20a-c are each located at the top or head of an oil and gas wellbore (not shown) that penetrates one or more subterranean formations (not shown) and are used in oil and gas exploration and production operations. To form the zipper manifold 30, the zipper modules 24a and 24b are interconnected with each other via fluid conduits 36a,b and block 204, and the zipper modules 24b and 24c are interconnected with each other via a fluid conduit 36c. Block 204 connects the zipper manifold 30 to the iron assembly 26 shown in
The wellheads 20a-c may be substantially identical to each other. Likewise, the frac trees 34a-c may be substantially identical to each other, and, therefore, in connection with
The illustrated embodiment is scalable to provide any number of interconnected zipper modules 24, OSL connections 26, and frac trees 34. To accommodate larger setups, the diameter of the intake pipe 202 delivering the frac fluid may be increased. For example, the pipe 202 may have an inner diameter ranging between 3-7 inches. In particular examples, the pipe 202 has an inner diameter of 3, 3.25, 3.5, 3.75, 4, 4.25, 4.5, 4.75, 5, 5.25, 5.5, 5.75, 6, 6.25, 6.5, 6.75, or 7 inches.
OSL connection 26a includes a straight-line connection of an OSL conduit 606a (which may be pipe or hose), a manually actuated gate valve 604a, and an automatically actuated gate valve 602a. Similar OSL connections are shown for OSL connections 26b and 26, having respective conduits 606b,c; manual gate vales 606b,c; and automatic gate valves 606b,c. As discussed in more detail below, these OSL connections 26a-c are merely examples. Other OSL connections 26 may use different combinations of gate, plug, or other types of valves as well as other lengths of conduits, or no conduits at all (e.g., just connect valves together.
The adapter 42 is connected to the lower gate valve 46 and facilitates connection of the wellhead 20a to a casing string (not shown) and/or a tubing string (not shown) extending within the associated wellbore. The production tee 48 is connected to the upper gate valve 44 and has a production wing valve 50a and a kill wing valve 50b connected thereto.
The multi-way block 52 is connected to the production tee 48, opposite the upper gate valve 44, and includes a block 58 that with a fluid conduit for receiving frac fluid from a zipper module 24 via an OSL connection 26 and directing the receive frac fluid downward through a fluid channel defined by the production tee 48, gate valves 44 and 46, and a production spool 34. Put another way, frac fluid enters the frac tree through the multi-way block 52 and passes down through an internal fluid channel in the wellhead 20. The multi-way block 52 may take the form of a three-way valve (as depicted in
In some embodiments, the multi-way block 52 is reinforced or includes a durable insert or layer of material (e.g., zirconia, partially stabilized zirconia, tungsten carbide, tungsten carbide nickel, tungsten carbide cobalt, titanium carbide, silicon nitride, sialon, silicon, silicon nitride, ceramic, or other hardened material) along the angled wall 98 and/or the back wall 99 of the shown internal passages. Such reinforcement dramatically reduces wear at the most impacted points of the multi-way block 52. Aside from a hardened material, these walls 98, 99 may be reinforced with steel, iron, or other metal; a dampening material (e.g., polyurethane); or a combination thereof.
The outlet segment 70 is connected between, and in fluid communication with, the production tee 48 and the swab valve 54 (shown, e.g., in
The outlet segment 70 defines an outlet passage 72 through which the outlet segment 70 is in fluid communication with the production tee 48 and the swab valve 54—along opposite sides. The outlet passage 72 extends through the outlet segment 70 along an axis 74. The outlet segment 70 also defines an angled inlet passage 76 via which the outlet segment 70 is in fluid communication with the inlet segment 68. The inlet passage 76 declines from horizontal axis 82 of inlet passage 80 in the inlet segment 68 toward upward and toward from the outlet passage 72 along an angled axis 78 that is oriented at angle α and β relative to the horizontal axis 82 of the inlet passage 80 and the vertical axis 74 of the outlet of the outlet passage. In operation, frac fluid enters the multi-way block 52 along passage 81 of the OSL connection 26, travels horizontally along passage 80, downward along passage 76, and either up toward the swab valve 54 or down toward the wellhead 20 via passage 72.
The inlet segment 68 defines an inlet passage 80 via which the inlet segment 68 is in fluid communication with a single straight-line fluid path 81 of the fluid conduit 32a (shown, e.g., in
The inlet segment 68 also defines an outlet passage 84 via which the inlet segment 68 is in fluid communication with the outlet segment 70. The outlet passage 84 extends downward toward the production spool 48 from the inlet passage 80 along an axis 86 oriented at an angle β with respect to the axis 82 of the inlet passage 80. In an embodiment, the outlet passage 84 of the inlet segment 68 is substantially coaxial with the inlet passage 76 of the outlet segment 70 (i.e., the axes 78 and 86 are substantially coaxial). In some embodiments, the sum of the angles α and β is about 90 degrees. The coaxial extension of the inlet and outlet passages 76 and 84 at the angles α and β, respectively, reduces wear and excessive turbulence in the block 58 by, for example, easing the change in the direction of fluid flow and eliminating blinded-off connections.
Additionally, in some embodiments, the multi-way block 52 is a 4- or 5-way block with valves (e.g., gate or plug) connected on each side, as shown in more detail in
Turning back to
The zipper module 24 is positioned on a transport skid 120 that includes lifting pegs 122a-d (the lifting peg 122d is not visible in
The zipper tree 89 includes upper and lower blocks 92 and 94 that have inner fluid passages therethrough and are used for supplying frac fluid to the zipper tree 89 and also—in embodiments like the interconnected frac tree setup 200 in
A rotatable upper elbow 100 is connected to the upper block 92 and is, in some embodiments, rotatable around the vertical axis of the zipper tree 89, as shown by curved arrow 105. The rotatable upper elbow 100 includes its own internal fluid passage for receiving frac fluid along the internal vertical axis of the zipper tree 89 and directing the frac fluid out of end 102 and toward a connected OSL connection 26 that is connected on the opposite side to a frac tree 34. Alternative embodiments may use different conduits for directing frac fluid out of the zipper tree 89. An elbow, swivel, or similar type of arcuate flow iron may alternatively be used. Also, not all embodiments include a rotatable upper elbow 100. A non-rotatable upper elbow 100, or swivel elbow, or the like, may alternatively be used to direct frac fluid out of the zipper tree 89 and toward the OSL connection 26.
In some embodiments, the upper block 92, lower block 93, and upper elbow 100 are coaxial along an internal fluid channel defined by the upper block 92, lower block 93, and upper elbow 100. Alternatively, any of the upper block 92, lower block 93, and upper elbow 100 may be eschew from any of the others central axes for the fluid channel.
In operation, the zipper module 24 is moved into place and adjusted to the right elevation. The rotation or swiveling of blocks 92 and 24 enable the zipper tree 89 to be aligned with other zipper trees 89 on other zipper modules or aligned with different fluid conduits providing frac fluid. The zipper tree 89 receives frac fluid in either the upper or lower block 92 or 94 and directs the received frac fluid up through an internal channel and out of the frac tree 89 through end 102. End 102 is connected to the OSL connections 26 described herein, which in turn pass the frac fluid to the frac trees 34 for eventual supply to wellheads 20.
Additionally or alternatively, an adjustable-length pipe (not shown) may be incorporated into the zipper tree 89 to provide an additional mechanism for raising or lowering the end 102 being connected to the OSL connection 26. In an example embodiment, the adjustable-length pipe is, includes, or is part of, the pipe 104. In another example embodiment, the adjustable-length pipe is, includes, or is part of the pipe 108. Thus, the adjustable-length pipe (not shown) of the zipper tree 89 is adjustable to facilitate alignment between the zipper module 24 and the frac tree 34.
In some embodiments, the OSL connection 26 includes an OSL conduit 606 connected to the end 102 of the elbow 100, followed by manual gate valve 604 and automatic gate valve 602 connected in series. In some embodiments, the OSL conduit 606, the manual gate valve 604, and the automatic gate valve 602 are coaxial along an internal fluid channel for passing frac fluid received from the zipper tree 89. The depicted embodiment is but one example of a configuration of an OSL connection 26. Additionally or alternatively, plug valves may be used instead of gate valves. Additionally or alternatively, two or more manual or two or more automatic gate valves may be connected in series. The OSL conduit 606, shown as a relatively short piece of pipe may, alternatively, be a flexible hose. In various embodiments, the OSL conduit 606 may be positioned between the gate valves 602 and 604, between the gate valve 602 and the multi-way block 52 of the frac tree 34, or may not be used. Thus, different combinations are fully contemplated by this disclosure than the illustrated OSL connection 26 in
The OSL connection 26 provides a straight line internal fluid channel, defined by the gate valves 602, 604 and the OSL conduit 606, between the zipper tree and the frac tree. At the frac tree 34, the OSL connection 26, via the depicted automatic gate valve 602, is connected to the multi-way block 52. This depicted multi-way block 52 is a 5-way block that receives frac fluid from the OSL connection 26 and provides an internal passage for the frac fluid to pass down through the frac tree 34 to the wellhead 20. The multi-way block 52 may include the internal passages shown in
Additionally, as shown in
Optionally, additional zipper modules may also be connected to the first zipper modules and, possibly, to other zipper modules, as shown at step 1108. These additional zipper modules are connected to respective frac trees at the site, as shown at 1110. Like the first zipper modules, OSL connections are created between the additional zipper modules and their respectively assigned frac trees through connecting valves and OSL fluid conduits along single additional straight-line fluid paths between the additional frac trees and the zipper modules, as shown at step 1112.
Once the zipper modules are connected to each other and their respective frac trees, fracturing fluid is pumped to the zipper modules, through the created OSL connections, and to the frac trees for delivery to wellheads, as shown at step 1114.
It is understood that variations may be made in the foregoing without departing from the scope of the present disclosure.
In some embodiments, the elements and teachings of the various embodiments may be combined in whole or in part in some or all of the embodiments. In addition, one or more of the elements and teachings of the various embodiments may be omitted, at least in part, and/or combined, at least in part, with one or more of the other elements and teachings of the various embodiments.
In some embodiments, while different steps, processes, and procedures are described as appearing as distinct acts, one or more of the steps, one or more of the processes, and/or one or more of the procedures may also be performed in different orders, simultaneously and/or sequentially. In some embodiments, the steps, processes and/or procedures may be merged into one or more steps, processes and/or procedures.
In some embodiments, one or more of the operational steps in each embodiment may be omitted. In some instances, some features of the present disclosure may be employed without a corresponding use of the other features. One or more of the above-described embodiments and/or variations may be combined in whole or in part with any one or more of the other above-described embodiments and/or variations.
In the foregoing description of certain embodiments, specific terminology has been resorted to for the sake of clarity. However, the disclosure is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes other technical equivalents which operate in a similar manner to accomplish a similar technical purpose. Terms such as “left” and right,” “front” and “rear,” “above” and “below,” and the like are used as words of convenience to provide reference points and are not to be construed as limiting terms.
In this specification, the word “comprising” is to be understood in its “open” sense, that is, in the sense of “including”, and thus not limited to its “closed” sense, that is the sense of “consisting only of.” A corresponding meaning is to be attributed to the corresponding words “comprise,” “comprised,” and “comprises” where they appear.
Although some embodiments have been described in detail above, the embodiments described are illustrative only and are not limiting, and those skilled in the art will readily appreciate that many other modifications, changes and/or substitutions are possible in the embodiments without materially departing from the novel teachings and advantages of the present disclosure. Accordingly, all such modifications, changes, and/or substitutions are intended to be included within the scope of this disclosure as defined in the following claims. In the claims, any means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Moreover, it is the express intention of the applicant not to invoke means-plus-function limitations for any limitations of any of the claims herein, except for those in which the claim expressly uses the word “means” together with an associated function.
Having described aspects of the disclosure in detail, it will be apparent that modifications and variations are possible without departing from the scope of aspects of the disclosure as defined in the appended claims. As various changes could be made in the above constructions, products, and methods without departing from the scope of aspects of the disclosure, it is intended that all matter contained in the above description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
This application claims priority to U.S. Provisional Application No. 62/530,088, filed Jul. 7, 2017 and entitled CONNECTION BETWEEN AN OIL AND GAS CRATURING TREE AND A MANIFOLD MODULE, the entire disclosure of which is hereby incorporated herein by reference for all intents and purposes.
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Entry |
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PCT Written Opinion, dated Oct. 1, 2018, regarding Application No. PCT/US2018/041160, 10 pages. |
Number | Date | Country | |
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20190010781 A1 | Jan 2019 | US |
Number | Date | Country | |
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62530088 | Jul 2017 | US |