US20260117635A1
PIPING SYSTEMS AND METHODS WITH AN AUGER ASSEMBLY
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
SPM Oil & Gas Inc.
Inventors
Matthew Treida, Brian Witkowski, Benjamin Engstrom
Abstract
Apparatuses, systems, and methods relate to a pipe system for oilfield operations. The pipe system includes a pipe having an inlet and an outlet. The pipe defines a cavity between the inlet and outlet configured to receive a flow of fluid containing a proppant. A fluid outlet is fluidly coupled to the cavity and located between the inlet and outlet of the pipe. An auger assembly installed in the cavity includes a helical blade extending at least partially between the inlet and outlet of the pipe. The helical blade directs a portion of the proppant through the fluid outlet. A first end support is coupled to a first end of the auger assembly and a second end support is coupled to a second end of the auger assembly. The first and second end supports engage the pipe to maintain a proper position of the helical blade within the cavity.
Figures
Description
TECHNICAL FIELD
[0001]This disclosure relates generally to pipe systems including reciprocating pumps, and in particular, to a pipe system having a low-pressure manifold including an auger assembly.
BACKGROUND
[0002]Pipe systems and reciprocating pumps are used in a variety of industrial settings. One use for such pipe systems and pumps is in the oil and gas industry. For example, pipe systems including one or more low pressure manifolds supply fluid, proppant, and the like to reciprocating pumps used in completion and stimulation operations including fracturing, cementing, acidizing, gravel packing, snubbing, and similar operations. Hydraulic well fracturing treatments are well known and have been widely described in the technical literature dealing with the present state of the art in well drilling, completion, and stimulation operations. Hydraulic fracturing is a process to obtain hydrocarbons such as natural gas and petroleum by injecting a mixture of water, chemicals, and proppant (e.g., sand, ceramic, etc.) at super high pressure into a wellbore to create cracks in deep rock formations. In a typical hydraulic fracturing operation, the subterranean well strata are subjected to tremendous pressures in order to create fluid pathways to enable an increased flow of oil or gas reserves that may then be brought up to the surface. The fracking fluids are pumped down the wellhead by high-pressure pumps located at the well surface. To reach such high-pressure pumps, fracking fluids generally first flow through one or more larger bore low-pressure manifolds which may be connected to each other via one or more conduits (e.g., hoses).
[0003]The low-pressure manifold(s) may be used to transport a mixture of fluid and proppant, for example, to the high-pressure pumps for pressurization. However, the momentum of the moving proppant creates resistance which discourages the proppant from flowing down the initial smaller transverse pipes that lead from the main low-pressure manifolds to each of the high-pressure pump inlets. Given the tendency of the proppant to continue moving down the low-pressure manifold, proppant accumulates at the end of each manifold resulting in a non-uniform distribution of proppant to the high-pressure pumps, causing increased wear to certain valve components that receive excessive volumes of proppant, and eventually resulting in rapid wear and/or premature failure of the pump components which receive excess proppant.
SUMMARY
[0004]A first aspect provided herein relates to a pipe system for oilfield operations. The pipe system includes a pipe having an inlet and an outlet. The pipe defines a cavity between the inlet and the outlet configured to receive a flow of fluid containing a proppant. A fluid outlet is fluidly coupled to the cavity and located between the inlet and the outlet of the pipe. An auger assembly installed within the cavity comprises a helical blade extending at least partially between the inlet and the outlet of the pipe. The helical blade is configured to direct a portion of the proppant through the fluid outlet. A first end support is coupled to a first end of the auger assembly and a second end support is coupled to a second end of the auger assembly. The first and second end supports engage the pipe to maintain a proper position of the helical blade within the cavity.
[0005]A second aspect provided herein relates to a frac iron system for oilfield operations. The frac iron system comprises a plurality of pipe systems. Each pipe system comprising a pipe having an inlet and an outlet, the pipe defining a cavity therebetween configured to receive a flow of fluid containing a proppant. The pipe also comprises a fluid outlet fluidly coupled to the cavity between the inlet and the outlet. The pipe system further comprises an auger assembly installed within the cavity and comprising a helical blade extending at least partially between the inlet and the outlet, the helical blade configured to direct a portion of the proppant through the fluid outlet, a support coupled to the auger assembly, the support engaging the pipe to align a longitudinal axis of the helical blade with a center of the cavity. Additionally, the frac iron system includes a low-pressure connector fluidly coupling the outlet of the pipe of a first pipe system of the plurality of pipe systems to an inlet of the pipe of a second pipe system of the plurality of pipe systems.
[0006]A third aspect provided herein relates to a method of manufacturing a pipe system for oilfield operations. The method comprises the steps of: providing a pipe having an inlet and an outlet, the pipe defining a cavity between the inlet and the outlet configured to receive a flow of fluid containing a proppant and comprising a fluid outlet fluidly coupled to the cavity; providing a helical blade; disposing the helical blade within the cavity such that the helical blade extends at least partially between the inlet and the outlet of the pipe; and coupling a first end of the helical blade to the pipe via a first end support and a second end of the helical blade to the pipe via a second end support, the first and second end supports engaging the pipe to maintain a proper position of the helical blade within the cavity.
[0007]This summary is illustrative only and is not intended to be in any way limiting. Other aspects, inventive features, and advantages of the devices or processes described herein will become apparent in the detailed description set forth herein, taken in conjunction with the accompanying figures, wherein like reference numerals refer to like elements.
BRIEF DESCRIPTION OF THE DRAWINGS
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DETAILED DESCRIPTION
[0019]The following detailed disclosure is better understood when read in conjunction with the figures. Before turning to the figures, which illustrate certain embodiments in detail, it should be understood that the present disclosure is not limited to the details or methodology set forth in the description or illustrated in the figures. It should also be understood that examples and terminology used herein are for the purpose of description only and should not be regarded as limiting.
[0020]A conventional pipe system for oilfield operations (e.g., fracking) may include a pipe as a component of a low-pressure manifold. As explained in more detail herein, the low-pressure manifold, via the pipe, draws fluid (e.g., fracking fluid, a mixture of water, chemicals, proppant, etc.) through a hollow tubular fluid passageway/cavity of the pipe that does not include any internal structure. A problem is that proppant, such as uniform-sized solid particles, in the fracking fluid can accumulate and become lodged and compacted in certain regions of the manifold, such as the downstream side bore furthest from the low-pressure manifold inlet. This means that some of the valves and valve seats (particularly those fluidly connected to downstream portions of the low-pressure manifold or sections of pipe) pass through/receive more of the proppant than others. The uneven proppant distribution results in irregular wear of the valves, valve seats, and other components with the downstream valves, valve seats, and other components requiring maintenance before others. The operator thus experiences shortening of the pipe system maintenance cycle and premature failure of the valves, valve seats, manifolds, pumps, and other components on the downstream side of the pipe system.
[0021]Traditional low-pressure piping designs to transport sand, proppant, and other particles (e.g., a cement mixture) to pumps for pressurization, to a high-pressure manifold, and/or to a well head face two main issues: reduced fluid velocity causing particles to settle, and resistance in smaller transverse pipes, for example, leading to uneven particle distribution and accumulation at the end of the pipe system and/or pipes thereof. To address this, an auger (e.g., a stationary auger) with a helical profile is installed within the piping, imparting a rotation to the fluid, increasing fluid velocity, and applying radial force to enhance particle distribution through fluid outlets of the low-pressure pipes of the low-pressure manifold. This solution ensures a more uniform particle/proppant flow, reducing wear on pipe system and/or frac iron components and extending their lifespan. The use of the auger assembly results in a more uniform distribution of the proppant along the length of the pipe/fluid cavity and leads to a more even wearing of valves, valve seats, etc. in the and/or downstream of the pipe system. The addition of the auger assembly also prolongs the maintenance cycle time period and meaningfully increases the operational runtime of the low-pressure manifold and other components of the pipe system and/or the frac iron system.
[0022]Turning to
[0023]When used in conjunction with a frac iron system (e.g., the frac iron system 200 illustrated in
[0024]Further, the pipe 112 may define a cavity 122 (e.g., hollow tubular fluid passageway located within an interior wall 144 of the pipe 112) between the inlet 114 and the outlet 118. The cavity 122 may be configured to receive a flow of fluid containing proppant. The pipe 112 and/or the cavity 122 may include an inside diameter 146 corresponding to the diameter of interior wall 144 of the pipe 112. (See, e.g.,
[0025]The pipe system 100 may also include one or more fluid outlets 126 fluidly coupled to the cavity 122. The fluid outlets 126 may be configured to divert/receive a portion of the fluid containing proppant flowing through the pipe 112. In some embodiments, the fluid outlets 126 are located between the inlet 114 and the outlet 118 of the pipe 112 as shown in
[0026]The fluid outlet 126 may draw fluid containing proppant from the low-pressure manifold 110 comprising the pipe 112. For example, one or more pumps 221 as shown in
[0027]Turning to
[0028]In the embodiment shown in
[0029]The frac iron system 200 may also include a plurality of pumps 220. One or more pumps 221 of the plurality of pumps 220 may be coupled to a respective pipe system 100. The one or more pumps 221 may comprise a pump fluid end 222 having a pump inlet 223 and a pump outlet 224 and a pump power end 225. The pumps 221 may include one or more plungers driven by a crankshaft to create alternately high and low pressures in a fluid chamber thereof. The power end 225 and the fluid end 222 are generally connected by a plurality of stay rods and tubes that make up a stay rod assembly. The power end 225 includes an internal crankshaft powered by an engine that drives the plungers. A suction manifold of the pump 221 provides a fluid passageway that delivers the fracking fluid to the pump fluid end 222. The pump fluid end 222 cylinders into which the plungers operate to draw fluid into the fluid chamber from the suction manifold (via a log manifold), and then forcibly push out the fluid at high pressure to the pump outlet 224. The pump outlet 224 then directs the pressurized fluid to the high-pressure manifold 130 (e.g., the high-pressure inlet pipe 136 of the flow iron 132 and downstream to the well head 250. In this manner, the reciprocating pump is used to forcefully deliver the fracking fluid at high pressure to the well head 250 and down the well. Specifically, fluid and proppant may flow from the cavity 122, through the fluid outlet 126 of the pipe 112, to a pump inlet 223 via a low-pressure conduit 240, then back to the high-pressure manifold 130 of a respective pipe system 100 via a high-pressure conduit 242.
[0030]Turning to
[0031]Turning to
[0032]Referring to
[0033]The auger assembly 400 includes a helical blade 404 that may extend along substantially the entire length 140 of the pipe 112. Alternatively, multiple shorter helical blades 404 coupled in series may be used. Referring also to
[0034]When disposed inside the cavity 122, an outer diameter 416 of the helical blade 404 may substantially span the inside diameter 146 of the cavity 122 and/or the pipe 112. In some embodiments, the outer diameter 416 of the helical blade 404 extends and stops short of the interior wall 144 of the pipe 112 and may form an annulus 420 (e.g., a gap, a circular open region through which fracking fluid may flow between the helical blade 404 and the pipe 112) between the outer edge of the helical blade 404 and the interior wall of the pipe 112. (See, e.g.,
[0035]
[0036]
[0037]As shown most clearly in
[0038]As shown most clearly in
[0039]The pipe system 100 and/or frac iron systems 200, 300 including an auger assembly 400 may be manufactured with a built-in auger assembly 400, or the auger assembly 400 may be retrospectively retrofitted into a pipe system 100 or the like (e.g., a pipe 112). In an alternate embodiment, the auger assembly 400 may employ multiple helical blade segments. In another embodiment, a series of spiral blades may be affixed to the wall of the pipe 112 (e.g., the interior wall 144. In yet another embodiment, an actuator may be coupled to the auger assembly 400 to rotate the helical blade 404 at a predetermined speed to further aid in the distribution of the proppant.
[0040]The features of the present invention which are believed to be novel are set forth below with particularity in the appended claims. However, modifications, variations, and changes to the exemplary embodiments described above will be apparent to those skilled in the art, and the novel pipe systems, frac iron systems, and auger assemblies described herein thus encompass such modifications, variations, and changes and are not limited to the specific embodiments described herein (e.g., features described or shown with respect to one figure or embodiment may be readily combined/interchanged with features of another embodiment and such modifications are expressly contemplated as within the scope of this disclosure).
INDUSTRIAL APPLICABILITY
[0041]The systems and methods described herein have industrial applicability in various use cases, environments, and settings that can be readily appreciated from the foregoing discussion. Specifically, in operation, the helical blade 404 of the auger assembly 400 effectively distributes the proppant in the frack fluid more evenly along the entire length 140 of the pipe system 100 and/or the pipe 112, which results in a more uniform distribution of proppant through each of the fluid outlets 126. In turn, uniformity of the proppant ensures that no component of the pipe system 100, frac iron system 200, 300, etc. receives excessive proppant, wear, and/or prematurely fails and causes unnecessary stoppages of operation/increased maintenance cycles when fracking, cementing, or the like.
[0042]Turning to
[0043]In some aspects, the method 600 may include step 604 of providing a helical blade 404 within the cavity 122 such that the helical blade 404 extends at least partially between the inlet 114 and the outlet 118 of the pipe 112. In this way, the helical blade 404 may alter the flow of the fracking fluid and specifically urge the proppant therein to flow towards the fluid outlets 126 (e.g., through transverse pipes) rather than maintaining momentum flowing downstream through the pipe 112.
[0044]In some aspects, the method 600 may include step 606 of coupling a first end of the helical blade 404 to the pipe 112 via a first end support 432 and a second end of the helical blade 404 to the pipe 112 via a second end support 452. For example, the first and second end supports 432, 452 may engage the pipe 112 (e.g., via fasteners 448, via friction, via being integrally formed as one unified component with the pipe 112, etc.) to maintain a proper position of the helical blade 404 and/or the auger assembly 400 within the cavity 122 of the pipe system 100. For example, and as best shown in
[0045]Similarly, the second end support 452 may be located adjacent to and/or at the second end 120 of the pipe 112 following insertion of the auger assembly 400 into the pipe 112 and/or coupling of the first end support 432 to the first end 116 of the pipe 112. The second end support 452 may be adjusted such that the second end support 452 becomes secured/coupled to the pipe 112 (e.g., via friction) and also centers the helical blade 404 along the length of the cavity 122. As illustrated in
[0046]As illustrated best in
[0047]In still further embodiments, other methods of coupling the first end support 432, the second end support 452, and/or another support 424 of the auger assembly 400 to the pipe 112. For example, one or more of the end supports may be replaced with a rubber stopper or other sealing member (e.g., a plug configured to fit tightly around an outer annular region of the cavity 122). In this way, the auger assembly 400 may be inserted into the cavity 122 until the rubber stopper or other member (e.g., a stiff rubber ring having approximately a 4-inch outer diameter to abut a 4-inch interior pipe diameter) is adjacent to an end of the pipe 112 and hammered/firmly inserted inside the cavity 122 of the pipe 112. In still further embodiments, ridges and/or channels may be formed in the interior wall 144 of the pipe 112 such that flanges, protrusions, or the like extending from the auger assembly 400 may be inserted into the channels to hold the auger assembly 400 in place (e.g., centered in the cavity 122).
[0048]In some aspects, the method 600 may include step 608 of providing a hollow support 428 such as a support bar, a support rod, a tubular member of sufficient strength having a hollow internal section to save weight yet provide rigidity to the helical blade 404, or the like, coupled to the helical blade 404 and extending along the longitudinal axis 412 thereof. In other embodiments, the hollow support 428 may be another type of support 424 such as a solid support bar and/or multiple support bars extending parallel to the longitudinal axis and coupled to the outer rim of the helical blade 404.
[0049]In some aspects, the method 600 may include step 610 of providing a second pipe 112 having a second inlet 114 and a second outlet 118, the second pipe 112 defining a second cavity 122 between the second inlet 114 and the second outlet 118 configured to receive the flow of fluid containing the proppant and comprising a second fluid outlet 126 fluidly coupled to the second cavity 122. In this way, proppant not diverted through the fluid outlet(s) 126 of the first pipe 112 (e.g., of the first pipe system 100a) may flow into the second pipe 112 of the second pipe system 100b. (See, e.g.,
[0050]In some aspects, the method 600 may include step 612 of providing a second helical blade 404 within the second cavity 122 such that the second helical blade 404 extends at least partially between the second inlet 114 and the second outlet 118 of the second pipe 112. The second helical blade 404, similar to the first helical blade 404 in the first pipe 112, may further increase the uniformity of the proppant which flows from the first pipe system 100a into the second pipe system 100b, thereby achieving the same and/or similar benefits to component longevity and increased operation time.
[0051]In some aspects, the method 600 may include step 614 of coupling a first end of the second helical blade 404 to the second pipe 112 via a first end support 432 and a second end of the second helical blade 404 to the second pipe 112 via a second end support 452, the first and second end supports 432, 452 engaging the second pipe 112 to maintain a proper position of the second helical blade 404 within the second cavity 122 of the second pipe 112. These supports may anchor the second helical blade 404 in the second pipe 112 in the same, a similar, or a different manner than the first helical blade 404 is secured inside the first pipe 112.
[0052]In some aspects, the method 600 may include step 616 of coupling the outlet 118 of the first pipe 112 of the first pipe system 100a to the second inlet 114 of the second pipe 112 via a low-pressure connector 212 as shown in
[0053]As utilized herein with respect to numerical ranges, the terms “approximately,” “about,” “substantially,” and similar terms generally mean+/−10% of the disclosed values, unless specified otherwise. As utilized herein with respect to structural features (e.g., to describe shape, size, orientation, direction, relative position, etc.), the terms “approximately,” “about,” “substantially,” and similar terms are meant to cover minor variations in structure that may result from, for example, the manufacturing or assembly process and are intended to have a broad meaning in harmony with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the disclosure as recited in the appended claims.
[0054]The term “coupled” and variations thereof, as used herein, means the joining of two members directly or indirectly to one another. Such joining may be stationary (e.g., permanent or fixed) or moveable (e.g., removable or releasable). Such joining may be achieved with the two members coupled directly to each other, with the two members coupled to each other using a separate intervening member and any additional intermediate members coupled with one another, or with the two members coupled to each other using an intervening member that is integrally formed as a single unitary body with one of the two members. If “coupled” or variations thereof are modified by an additional term (e.g., directly coupled), the generic definition of “coupled” provided above is modified by the plain language meaning of the additional term (e.g., “directly coupled” means the joining of two members without any separate intervening member), resulting in a narrower definition than the generic definition of “coupled” provided above. Such coupling may be mechanical, electrical, or fluidic.
[0055]References herein to the positions of elements (e.g., “top,” “bottom,” “above,” “below”) are merely used to describe the orientation of various elements in the figures. It should be noted that the orientation of various elements may differ according to other embodiments, and that such variations are intended to be encompassed by the present disclosure.
[0056]Although the figures and description may illustrate a specific order of method steps, the order of such steps may differ from what is depicted and described, unless specified differently above. Also, two or more steps may be performed concurrently or with partial concurrence, unless specified differently above. Such variation may depend, for example, on the hardware systems chosen and on designer choice. All such variations are within the scope of the disclosure.
[0057]It is important to note that the construction and arrangement of the various embodiments is illustrative only. Additionally, any element disclosed in one embodiment may be incorporated or utilized with any other embodiment disclosed herein.
Claims
What is claimed is:
1. A pipe system for oilfield operations, the pipe system comprising:
a pipe having an inlet and an outlet, the pipe defining a cavity between the inlet and the outlet configured to receive a flow of fluid containing a proppant;
a fluid outlet fluidly coupled to the cavity and located between the inlet and the outlet of the pipe;
an auger assembly installed within the cavity and comprising:
a helical blade extending at least partially between the inlet and the outlet of the pipe, the helical blade configured to direct a portion of the proppant through the fluid outlet; and
a first end support coupled to a first end of the auger assembly and a second end support coupled to a second end of the auger assembly, the first and second end supports engaging the pipe to maintain a proper position of the helical blade within the cavity.
2. The pipe system of
3. The pipe system of
4. The pipe system of
the fluid outlet includes a plurality of fluid outlets disposed along a length of a side of the pipe, each of the plurality of fluid outlets coupled to a conduit configured to draw fluid from the cavity; and
the auger assembly is configured to increase a uniformity of an amount of the proppant directed through each of the plurality of fluid outlets.
5. The pipe system of
a hollow support coupled to the helical blade and extending along a longitudinal axis thereof, the hollow support having a first end coupled to the first end support and a second end coupled to the second end support.
6. The pipe system of
a mounting block coupled to an interior wall of the pipe;
a brace coupled to the mounting block, the brace extending across a center of the cavity; and
an adaptor configured to couple the hollow support to the brace such that the longitudinal axis of the helical blade substantially aligns with the center of the cavity.
7. The pipe system of
a first brace configured to abut an interior wall of the pipe;
a housing extending across a center of the cavity, the housing having a first end coupled to the first brace and a second end opposite the first end;
an adaptor configured to couple the hollow support to the housing such that the longitudinal axis of the helical blade substantially aligns with the center of the cavity;
an extending support configured to adjustably extend from the housing; and
a second brace coupled to the second end of the housing via the extending support, the second brace configured to abut the interior wall of the pipe.
8. A frac iron system comprising the pipe system of
a low-pressure manifold comprising the pipe;
a high-pressure manifold downstream of the fluid outlet and configured to receive a pressurized flow of fluid containing the proppant; and
a skid coupling the low-pressure manifold to the high-pressure manifold via a mounting feature.
9. A frac iron system for oilfield operations, the frac iron system comprising:
a plurality of pipe systems, each pipe system comprising:
a pipe having an inlet and an outlet, the pipe defining a cavity therebetween configured to receive a flow of fluid containing a proppant;
a fluid outlet fluidly coupled to the cavity between the inlet and the outlet;
an auger assembly installed within the cavity and comprising:
a helical blade extending at least partially between the inlet and the outlet, the helical blade configured to direct a portion of the proppant through the fluid outlet;
a support coupled to the auger assembly, the support engaging the pipe to align a longitudinal axis of the helical blade with a center of the cavity; and
a low-pressure connector fluidly coupling the outlet of the pipe of a first pipe system of the plurality of pipe systems to an inlet of the pipe of a second pipe system of the plurality of pipe systems.
10. The frac iron system of
11. The frac iron system of
12. The frac iron system of
13. The frac iron system of
a low-pressure manifold comprising the pipe and the low-pressure connector;
a high-pressure manifold comprising a flow iron downstream of the fluid outlet and configured to receive a pressurized flow of fluid containing the proppant; and
a skid coupling the low-pressure manifold to the high-pressure manifold via a mounting feature.
14. The frac iron system of
a high-pressure connector fluidly coupling an outlet of the flow iron of the first pipe system of the plurality of pipe systems to an inlet of the flow iron of the second pipe system of the plurality of pipe systems.
15. A method of manufacturing a pipe system for oilfield operations, the method comprising:
providing a pipe having an inlet and an outlet, the pipe defining a cavity between the inlet and the outlet configured to receive a flow of fluid containing a proppant and comprising a fluid outlet fluidly coupled to the cavity;
providing a helical blade within the cavity such that the helical blade extends at least partially between the inlet and the outlet of the pipe; and
coupling a first end of the helical blade to the pipe via a first end support and a second end of the helical blade to the pipe via a second end support, the first and second end supports engaging the pipe to maintain a proper position of the helical blade within the cavity.
16. The method of
the fluid outlet comprises a plurality of fluid outlets; and
the helical blade is configured to direct a portion of the proppant through the plurality of fluid outlets to increase a uniformity of an amount of the proppant directed through each of the plurality of fluid outlets.
17. The method of
inserting the helical blade into the cavity of the pipe via the first end of the pipe until the first end support is adjacent to a stop at the inlet of the pipe and the second end support is adjacent to the outlet of the pipe;
coupling the first end support to the stop via a brace; and
coupling the second end support to an interior wall at the outlet of the pipe via a friction surface.
18. The method of
centering the helical blade along a length of the cavity of the pipe by actuating an extending support of at least one of the first end support or the second end support.
19. The method of
providing a second pipe having a second inlet and a second outlet, the second pipe defining a second cavity between the second inlet and the second outlet configured to receive the flow of fluid containing the proppant and comprising a second fluid outlet fluidly coupled to the second cavity;
providing a second helical blade within the second cavity such that the second helical blade extends at least partially between the second inlet and the second outlet of the second pipe;
coupling a first end of the second helical blade to the second pipe via a first end support and a second end of the second helical blade to the second pipe via a second end support, the first and second end supports engaging the second pipe to maintain a proper position of the second helical blade within the second cavity; and
coupling the outlet of the pipe to the second inlet of the second pipe via a low-pressure connector.
20. The method of
coupling the fluid outlet of the pipe and the second fluid outlet of the second pipe to a high-pressure manifold.