Patent Application
20250188826
Hydraulic fracturing systems utilize fracturing fluid to collect gas and/or oil from geological formations deep below the earth's surface. One or more fracturing pumps are used to pressurize the fracturing fluid to a level which exceeds the tensile strength of the subterranean geological formations below the earth's surface. When distributed into a wellbore, the highly pressurized fluid generates micro fissures or cracks within the geological formations surrounding the wellbore. After the wellbore is depressurized, proppant material in the fracturing fluid remain in the fissures to hold the fissures open so that oil and/or gas trapped within the geological formations can be harvested through the wellbore.
In an example of the present disclosure, a system and a method for interconnecting components of a hydraulic fracturing system is disclosed. The method can include positioning a plurality of pumps adjacent to a manifold. The pumps and the manifold can be configured to operate within the hydraulic fracturing system. Each of the plurality of pumps can have a respective pump connection. The manifold can have a plurality of manifold connections configured to be connected to each of the plurality of pumps. The method can also include coupling a first end of a first flexible hose to one of the respective pump connections. The method can further include coupling a second end of the first flexible hose to one of the plurality of manifold connections. The method can include coupling a first end of a second flexible hose to one of the respective pump connections. The method can also include coupling a second end of the second flexible hose to one of the plurality of manifold connections. The method can include positioning a portion of the first flexible hose of the plurality of flexible hoses adjacent to a portion of the second flexible hose of the plurality of flexible hoses. The method can further include wrapping at least one safety restraint around each respective portion of the first and second flexible hoses to tether the first flexible hose to a pump, to the manifold, or to a second flexible hose that is tethered to a pump, or to the manifold.
The hydraulic fracturing system can have a blender configured to receive and combine water, sand, and chemicals into a slurry. The plurality of pumps can receive the slurry. The plurality of pumps can be configured to pressurize the slurry and deliver the pressurized slurry to the manifold. In one example, the method can further include coupling a first end of a third flexible hose to one of the respective pump connections; coupling a second end of the third flexible hose to one of the plurality of manifold connections; positioning a portion of the third flexible hose of the plurality of flexible hoses adjacent to the portion of the first and second flexible hoses; and wrapping the at least one safety restraint around each respective portion of the first, second, and third flexible hoses to tether the third flexible hose to a pump, to the manifold, or to a second flexible hose that is tethered to a pump, or to the manifold.
In some examples, the plurality of flexible hoses can have an inner diameter of at least one inch. The manifold can be a monoline system having multiple segment pods or a mobile trailer that can be either a monoline or multiple flow system trailer, as has been historically used in the industry. A portion of the safety restraint can be wrapped substantially perpendicular relative to a longitudinal axis defined by the first flexible hose or the second flexible hose. The plurality of pumps can be configured to be transportable to a fracturing site using one or more trucks.
Features from any of the disclosed embodiments can be used in combination with one another, without limitation. In addition, other features and advantages of the present disclosure will become apparent to those of ordinary skill in the art through consideration of the following detailed description and the accompanying drawings.
The drawings illustrate several embodiments of the present disclosure, wherein identical reference numerals refer to identical or similar elements or features in different views or embodiments shown in the drawings.
Utilizing hydraulic fracturing techniques to accelerate oil and gas production from geological formations typically includes pumping highly pressurized fracturing fluid (i.e., a mixture of water, sand, and chemicals, which are blended into a slurry) into a wellbore. One or more pumps (e.g., pump trucks) are used in conjunction with a manifold to pressurize the fracturing fluid to a pressure commonly ranging from 5,000 PSI to 20,000 PSI, or more. The pressurized fracturing fluid is thereafter delivered to the wellhead and pumped into the wellbore. Rigid metal pipes capable of withstanding the highly pressurized fracturing fluid have been used to couple the multitude of mechanical systems of the fracturing site to one another. Rigid stalks of steel tubular pipe, referred commonly in the industry as iron, have been interconnected using connectors (e.g., chiksan swivel joints) to couple each pump to the manifold. The metal pipes and connectors can form a rigid flow line that interconnects the various components of the hydraulic fracturing system.
As used in this specification, the terms “manifold”, “missile”, “monoline”, and “pods” can be used interchangeably. The singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, the term “a missile” can be intended to mean a single means to collect and distribute fluid or a combination of means to collect and distribute fluid. Additionally, or alternatively, “a manifold” can be intended to mean one or more manifolds, or a combination thereof.
Rigid metal pipes and connectors, however, introduce significant insufficiencies within the fracturing system. For example, because each fracturing site has a unique topographical landscape, the rigid metal pipes and connectors must be uniquely assembled to accommodate elevation variations and other unique features of the fracturing site. Consequently, each connector increases the cost of the project and also increases the time it takes to set up the fracturing site. Moreover, each additional connection in the flow line creates a potential location for failure (e.g., a leak). Although rated for high pressure use, the rigid metal pipes and the required connectors are susceptible to failure induced by shifting machinery, vibration, cavitation, cyclic fatigue, and pressure spikes. To inhibit movement of the metal pipes, the metal pipes can be affixed to the pump via a mounting system, but mounting the metal pipes to the pump also increases the cost and complexity of each pump truck along with increasing the setup time and cost of each fracturing site. Moreover, if the metal pipe needs to be moved to a new fluid outlet on the pump, the entire mounting system must be removed and replaced with a new mounting system that accommodates the new position of the fluid outlet.
The metal pipe and connectors can be dangerous when high pressure causes a metal pipe, connector, or both to catastrophically fail (e.g., a line rupture). Flow line safety restraints are therefore wrapped around each section of straight metal pipe and each connector to ensure the safety of personnel and equipment on the fracking site. For example, a first safety restraint is positioned to extend parallel to each length of metal pipe and each connector. Thereafter, many safety restraints are wrapped around each straight section of metal pipe and the first safety restraint to effectively tether the entire length of the flow line together. A typical fracturing site often includes many pumps coupled to the manifold by respective flow lines. Each of these flow lines must be secured using safety restraints. Unfortunately, positioning flow lines constructed using rigid metal pipe and connectors within close proximity to adjacent flow lines is challenging given the dimensions of the pumps. A large quantity of safety restraints are fitted within the fracturing system due to the complexity of fitting iron within a compressed are to allow for the required points of freedom. Again, the large number of safety restraints increases the time it takes to set up the fracturing site and the overall cost of the fracturing site.
In one aspect of the present disclosure, a flexible pipe or hose (i.e., a flexible flow line) capable of withstanding pressure in excess 15,000 PSI is utilized to couple various components of a fracturing system. For example, a flexible pipe or hose can be used to connect a pump to the manifold. Interconnecting components of the fracturing system using a flexible pipe can significantly reduce the cost of the system by reducing the number of connectors and safety restraints utilized to safely and appropriately operate the system. Utilizing flexible pipe or hoses also decreases the likelihood of system failure by reducing the number of connections, thereby reducing the risk of a leak. Additionally, flexible pipe can be quickly and easily installed, which substantially reduces set-up time. Furthermore, flexible pipe can be routed within a smaller area, thereby reducing the overall footprint of the fracturing site. Flexible pipe or hose can absorb and even dampen system vibrations, reducing the likelihood of failure relating to shifting machinery, vibration, cavitation, cyclic fatigue, and pressure spikes. In short, utilizing flexible pipe or hose increases the durability of the flow line while reducing the cost of operating the fracturing site and the time it takes to set up/maintain the fracturing site.
Flexible hose can be used to interconnect multiple components of the fracturing site. For example, flexible hose can be used to connect one or more pumps to a manifold or missile. In fracturing systems that include a monoline system having two or more segment pods, each pod can be interconnected to another pod and/or a pump using flexible hose or pipe. Interconnecting segment pods of a monoline system with flexible hose can be advantageous to quickly and simply route the hose around obstacles or to interconnect pods positioned on uneven terrain. Flexible hose also permits the pods to be positioned or repositioned in a staggered orientation to reduce the overall footprint of the fracturing site or to work around obstacles on the fracturing site.
At a fracturing site that couples multiple pumps to a manifold (or segment pods of a monoline system) using flexible hoses, many of the hoses can be positioned adjacent to one another, thereby drastically reducing the number of safety restraints needed to tether the flexible hoses together, for instance if restrained in pairs. Moreover, flexible pipe or hose also requires fewer safety restraints because the flexible pipe is continuous along the length of the flow line. In contrast, the traditional method of using multiple straight segments of stalk iron pipe interconnected by swivels requires a restraint at each end of each straight segment to safely retain the flow line in case of rupture and to prevent the iron pipe from becoming a deadly projectile if a rupture occurs.
In some embodiments, a method for interconnecting components of a hydraulic fracturing system can include positioning a plurality of pumps near or adjacent to a manifold of a fracturing system. Each of the plurality of pumps includes a respective pump connection. The manifold includes a plurality of manifold connections. The method includes coupling a first end of a first flexible hose (i.e., flexible flow line) with one of the respective pump connections. The method also includes coupling a second end of the first flexible hose to one of the plurality of manifold connections. The method can also include coupling a first end of a second flexible hose with one of the respective pump connections. The method can further include coupling a second end of the second flexible hose to another one of the plurality of manifold connections. The method can also include positioning a portion of first flexible hose of the plurality of flexible hoses adjacent to a portion of the second flexible hose of the plurality of flexible hoses. For example, a mid-portion of the first flexible hose can be positioned next to a mid-portion of the second flexible hose.
As used in this specification, the term “pipe” and “hose” are used interchangeably. The singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. Thus, for example, the term “a hose” is intended to mean a single hose or a combination of hoses. Similarly, “a pipe” is intended to mean one or more pipes, or a combination thereof.
Safety restraints 116 must be positioned around each end of each straight section of metal pipe 112 to sufficiently restrain the flow line 110 during failure. Even a single straight section of metal pipe 112 that is not wrapped by a safety restraint 116 can injure personnel and/or destroy other equipment during a catastrophic failure of that flow line 110.
Each pump 306 is coupled to the missile 304 by a set of flexible flow lines 310. For example, each pump 306 can have a set of connections configured to interlock, engage, or otherwise couple to a fitting affixed to each end of the flexible flow line 310. Similarly, the missile or manifold 304 can include a set of connections configured to interlock, engage, or otherwise couple to a fitting affixed to each end of the flexible flow line 310.
Each of the flexible flow lines 310 can transfer fluid (e.g., fracturing fluid) at rate between 3 and 30 barrels per minute (bpm). For example, each flexible flow line 310 can transfer at least 3 bpm, between about 3 bpm and about 7 bpm, between about 7 bpm and about 15 bpm, between about 15 bpm and about 20 bpm, or less than 30 bpm. Each of the flexible flow lines 310 can be rated to transfer fluid (e.g., fracturing fluid) at pressures between 5,000 psi and 20,000 psi. For example, each flexible flow line 310 can transfer fluid at a pressure of at least 300 psi, between about 300 psi and about 1,000 psi, between about 1,000 psi and about 5,000 psi, between about 5,000 psi and about 10,000 psi, between about 10,000 psi and about 15,000 psi, or less than 30,000 psi. Each of the flexible fluid flow lines 310 can have a diameter (e.g., diameter of the hose) of between 1 inch and 5 inches. In some examples, the inner diameter of the flexible fluid flow lines 310 can be greater than 2 inches, greater than 3 inches, greater than 4 inches, greater than 5 inches, greater than 6 inches, greater than 7 inches, or greater than 8 inches. In some examples, the inner diameter of the plurality of flexible hoses can be between about 1 inch and about 2 inches, between about 2 inches and about 3 inches, between about 3 inches and about 4 inches, between about 4 inches and about 5 inches, between about 5 inches and about 6 inches, between about 6 inches and about 7 inches, between about 7 inches and about 8 inches, or between about 8 inches and about 12 inches. For example, one or more of the flexible flow lines 310 can have a diameter of 3 inches. In some examples, one or more of the flexible flow lines 310 can have a diameter that is dissimilar from a diameter of another one of the flexible flow lines 310.
In some examples, at least one of the flexible flow lines 310 can be 3 inches in diameter and flow about 6 bpm of fluid under about 11,000 psi. Each of the flexible flow lines 310 can define a singular flexible fluid path between the respective pumps 306 and the missile 304. The singular fluid path defined by the flexible flow lines 310 eliminates the need for connectors between segmented piping which can leak when exposed to high pressure. Unlike rigid metal pipe, the flexible flow lines 310 can be easily routed between a pump 306 and the missile 304, regardless of surface elevation discrepancies between the pump 306 and the missile 304 or obstacles on the fracturing site (e.g., guy wires, mobile trailers, auxiliary equipment, wellhead blowout preventor controls, etc.) Thus, the use of the flexible flow lines 310 reduce the overall cost, footprint, and setup time of the hydraulic fracturing system 300.
The flexible flow lines 310 also facilitate adjustment and mobility of the various components of the hydraulic fracturing system 300 as needed. For example, the missile 304 may need to be repositioned to create space for an additional wellhead, manifold, or other piece of fracturing equipment. The flexible flow lines 310 can accommodate shifting the missile while the flow lines 310 remain attached, whereas adjustment of rigid metal flow lines requires significant time for disassembly, design, part collection, and reconfiguration to conform to the new position of the missile. Even if the components are disconnected for repositioning, the present flexible flow lines 310 are easily disconnected by the release of one connection at each end of the flexible flow line, ensuring that any repositioning or modification of the fracturing system 300 is less complicated and faster than performing the process with rigid fixed pipes.
Although the flexible flow lines 310 are depicted in
In some examples, the flexible flow lines 310 can additionally or alternatively be coupled to legacy missiles, manifolds, pods, or any other equipment to replace rigid metal high-pressure flow lines (e.g., rigid metal high-pressure flow lines 110) being used to flow fluid to the wellhead 308. As used herein, the term “legacy” can refer to any pre-existing or previously arranged conventional hydraulic fracturing systems (e.g., conventional hydraulic fracturing system 100) currently utilizing rigid metal high-pressure flow lines (e.g., rigid metal high-pressure flow lines 110) to procure oil and/or gas from geological formations.
While the safety restraints 316 are depicted as tethering or coupling the flexible flow lines 310 to the missile 304, those having skill in the art will appreciate that the configuration of safety restraints 316 shown in
While the current configuration is described as including a single high pressure flexible flow line connecting the pump and the missile, in one embodiment, a single hose can be connected to the missile at a first and can include a hose connection at a second end. This configuration allows for a high-pressure hose connected at the outlet of the pump. According to this exemplary embodiment, a pump can be connected to the manifold through two high-pressure hoses. When the pump is to be disconnected to remove it from pumping (say for maintenance), the two high-pressure hoses can be decoupled and another pump with its own dedicated high-pressure hose can then be rigged in to connect with the first high-pressure hose, without removing the connection with the missile.
The method 500 optionally includes, at act 502, positioning a plurality of pumps adjacent to a manifold. The pumps and manifold can be configured to operate within a hydraulic fracturing system and each of the plurality of pumps can include a respective pump connection. Similarly, the manifold can include a plurality of manifold connections which coincide with the pump connections. Method 500 optionally further includes, at act 504, coupling a first end of a first flexible hose to one of the respective pump connections. The flexible hose can be connected to the pump connections by any number of connection methods currently known or developed in the future, including a Grayloc® connector, a C-hub connector, a flange connector, and/or wings on a threaded connection, such as a hammer union. Additionally, according to one embodiment, the connection system can include any number of quick connect systems, such as novel locking connections, to further enhance the connections of the high-pressure hoses. The use of quick connect systems would further speed rig-up times while exponentially expanding overall reliability of the entire high-pressure system. Alternatively, various and different connection systems may be used to connect the flexible hose to a pump, while a different connection system can be used to hydraulically connect the flexible hose to a manifold or monoline. According to one embodiment, the connection used at the manifold or monoline can have an integral larger end at the manifold where, according to one embodiment, one or more clamps secured to the manifold or monoline can be actuated to engage a corresponding feature defined in the end of the hose, such as a flat surface. The engagement can then be maintained, according to one embodiment, by mechanical or hydraulic pressure. Such a connection is often defined as a hydraulic/dry-break connection. In one example, preset stations can be formed to receive each pump truck and to establish a consistent connection to the missile, to eliminate any need to handle the flexible hose.
Method 500 further includes, at act 506, coupling a second end of the first flexible hose to one of the plurality of manifold connections. The flexible hose can be connected to the manifold connections by any number of connection methods currently known or developed in the future, including threading wings onto a threaded connection, mechanical actuated connections, or using the hydraulic connection system detailed above.
The method 500 also includes, at act 508, coupling a first end of a second flexible hose to one of the respective pump connections. The method 500 optionally includes, at act 510, coupling a second end of the second flexible hose to one of the plurality of manifold connections.
The method 500 optionally includes coupling a first end of a third flexible hose to one of the respective pump connections; coupling a second end of the third flexible hose to one of the plurality of manifold connections; positioning a portion of the third flexible hose adjacent to the portions of the first and second flexible hoses; and wrapping at least one safety restraint around each respective portion of the first, second, and third flexible hoses to tether the third flexible hose to the first, to the second, or to both the first and second flexible hoses.
For example, as shown in
In some examples, the hose connector 604 can also include a seal (not shown). The seal can include a gasket ring, a metal seal ring, or an O-ring disposed between the male fitting 606 and the female fitting 608. The seal can be made of silicon, neoprene, rubber, fiberglass, natural or synthetic fibers, or other suitable materials.
While various embodiments of the hydraulic fracturing system, methods and devices have been described above, it should be understood that they have been presented by way of example only, and not limitation. Where methods and steps described above indicate certain events occurring in certain order, those of ordinary skill in the art having the benefit of this disclosure would recognize that the ordering of certain steps may be modified and such modifications are in accordance with the variations of the invention. Additionally, certain of the steps may be performed concurrently in a parallel process when possible, as well as performed sequentially as described above. The embodiments have been particularly shown and described, but it will be understood that various changes in form and details may be made.
For example, although various embodiments have been described as having particular features and/or combinations of components, other embodiments are possible having any combination or sub-combination of any features and/or components from any of the embodiments described herein. In addition, the specific configurations of the various components can also be varied. For example, the size and specific shape of the various components can be different than the embodiments shown, while still providing the functions as described herein.
This application is a continuation-in-part of U.S. application Ser. No. 18/674,682, filed 24 May 2024, which is a continuation of U.S. application Ser. No. 18/151,085, filed 6 Jan. 2023, which is a continuation of U.S. application Ser. No. 17/100,471, filed 20 Nov. 2020, now patented as U.S. Pat. No. 11,549,348, which issued on 10 Jan. 2023, which claims priority to U.S. Provisional Application No. 62/941,459, filed 27 Nov. 2019, the contents of all of which are incorporated herein by reference in their entireties.
| Number | Date | Country | |
|---|---|---|---|
| 62941459 | Nov 2019 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 18151085 | Jan 2023 | US |
| Child | 18674682 | US | |
| Parent | 17100471 | Nov 2020 | US |
| Child | 18151085 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 18674682 | May 2024 | US |
| Child | 19059838 | US |
