Pump With Segmented Fluid End Housing and In-Line Suction Valve
A plunger pump fluid end in which the suction valve and seat is aligned with the plunger and the fluid end housing is constructed with multiple modules. Modules are held in a rigid assembly by staybolts that connect to the power end of the plunger pump. Said staybolts pass though bores in the central fluid module and the suction seat module and bound by a conventional threaded nut. Packing box modules are bound to the central fluid module by bolts that also pass through separate bores in the same central module. A suction valve spring retainer/plunger spacer within the plunger bore of the assembly shields the intersection of the plunger bore and the discharge bore from destructive erosion damage.
This patent application is a Divisional of, and claims priority to, U.S. Non-Provisional patent application Ser. No. 15/732,441, filed on Nov. 13, 2017. This patent application further claims priority to U.S. Non-Provisional patent application Ser. No. 15/330,213, filed on Aug. 23, 2016, and also claims priority to U.S. Non-Provisional patent application Ser. No. 15/330,212, filed on Aug. 23, 2016. Each of the aforementioned patent applications, by this reference, are incorporated herein for all purposes.
FIELD OF THE INVENTIONThe invention relates generally to high-pressure plunger pumps used, for example, in oil field operations. More particularly, the invention relates to a modular fluid end design with an internal bore configuration that improves flow, improves fluid end filling, and incorporates structural features for stress-relief in high-pressure plunger pumps.
BACKGROUNDEngineers typically design high-pressure oil field plunger pumps in two sections: the (proximal) power section and the (distal) fluid section. The power section usually comprises a crankshaft, reduction gears, bearings, connecting rods, crossheads, crosshead extension rods, etc. Power and fluid sections are commonly referred to in the industry, and hereafter in the application, as the power end and fluid end, respectively. Fluid ends usually comprise a plunger pump fluid end housing with multiple internal cavities or fluid chambers, each chamber having a suction valve in a suction bore, a discharge valve in a discharge bore, and a plunger in a plunger bore, plus high-pressure seals, retainers, etc.
Valve terminology varies according to the industry, e.g., pipeline or oil field service, in which the valve is used. In some applications, the term “valve” means just the moving element or valve body. In the present application, however, the term “valve” includes other components in addition to the valve body, e.g., various valve guides to control the motion of the valve body, the valve seat, and/or one or more valve springs that tend to hold the valve closed, with the valve body reversibly sealed against the valve seat.
Valve and seat sizing design is a compromise between competing objectives in fluid end design. Traditionally engineers have wanted to use suction valve and seat designs of as a large a size as possible, as the larger the flow area in the valve and seat, the lesser the flow restriction. Flow restrictions reduce fluid energy which hinders the complete filling of the fluid chamber and the volumetric efficiency of the pump. Incomplete filling of the fluid chamber can cause a rough running pump. Additionally, larger valve and seat sizes reduce fluid velocity through the valve and seats. High fluid velocity contributes to erosion damage of the valve seal and leads to premature seal failure of the valve. For additional detail on valve erosion damage read the teaching of U.S. Pat. No. 9,416,887. The disadvantage of larger valve and seat sizes is the greater the size and weight of the fluid end housing necessary to contain the larger size valve and seat. Larger valve and seat sizes also result in higher valve loads and higher stresses on the fluid end housing which can result in premature structural failure of the housing. In rare instances in the prior art, suction valves and seats were slightly larger than discharge valves and seats. The theoretical reason for this sizing was based on the belief that greater flow area was necessary in the suction valves and seats to reduce flow restrictions than comprised fluid energy in filling the fluid chamber on the suction stroke. Further, many designers observed that the fluid in the discharge stroke inherited great fluid energy from the applied power of the moving plunger and thus smaller valve and seat sizing could be applied to the discharge valves and seats. This reasoning ignores the requirement to reduce fluid velocity in both sets of valves and seats to prevent erosion damage and premature failure to valve seals.
Similarly in the prior art, the suction port and discharge were almost always maximized to reduce flow restrictions. The suction port and discharge port are the volumetric bores directly upstream and feeding the suction valve/seat and discharge valve/seat, respectively. The respective bore of these respective ports would typically be maximized by boring the port to the small diameter of the taper in the fluid end housing utilized in capturing and securing the suction or discharge seat. This design practice was justified in the suction port because of the need to preserve fluid energy by reducing flow restrictions. By default, the same practice was utilized for the discharge port. As will be discussed later in this application, a large discharge port is not warranted.
Each individual bore in a plunger pump fluid end housing is subject to fatigue due to alternating high and low pressures which occur with each stroke of the plunger cycle. Conventional fluid end housings, also referred to as Cross-Bore blocks, typically fail due to fatigue cracks in one of the areas defined by the intersecting suction, plunger, access and discharge bores as schematically illustrated in
To reduce the likelihood of fatigue cracking in the high-pressure plunger pump fluid end housings described above, a Y-block housing design has been proposed. The Y-block housing design, which is schematically illustrated in
Both cross-bore blocks and Y-blocks have several major disadvantages when used to pump heavy slurry fluids as typically utilized in oilfield fracturing service. A first disadvantage is related to the feeding of the fluid chamber on the suction stroke of the pump. Upon passing through the suction valve, the fluid must make a 90 degree turn in a cross-bore housing, or a 60 degree turn in a Y-block housing, into the plunger bore as illustrated in
Fluid energy is normally added to the fluid by small supercharging pumps upstream from the plunger pump. Fluid energy is necessary to overcome fluid inertia and ensure complete filling of the fluid chamber on the suction stroke. If the fluid could enter the fluid chamber in a linear or straight path, less fluid energy would be lost.
The second disadvantage of Cross-Bore blocks and Y-blocks relates to the large intersecting curved areas where the various bores intersect. Because the suction bore above the suction valve is almost as large as the plunger bore, the intersection area of the suction bore with the plunger bore is particularly large, as illustrated in
As shown in
The amount of stress at the intersecting bores of conventional fluid end housings is defined by the magnitude of the “Bore Intersection Pitch” as illustrated in
Previously filed U.S. Non-Provisional patent application Ser. No. 15/330,212, filed on Aug. 23, 2016, and U.S. Non-Provisional patent application Ser. No. 15/330,213, filed on Aug. 23, 2016, featured an “in-line” design and addressed many of the issues of failure due to high stress and “Bore Intersection Pitch.” These applications also addressed the loss of fluid energy at the intersection of the suction bore and plunger bore in typical cross bore designs illustrated in
One of the major shortcomings of the U.S. application Ser. Nos. 15/330,212 and 15/330,213 relates to maintenance complications encountered when changing the plunger or plunger packing. Fluid ends built to Ser. Nos. 15/330,212 and 15/330,213 require removal of the entire fluid end assembly to access the damaged or worn parts. This problem could be addressed with a two-piece plunger design; however, such plungers are difficult to access for maintenance and are prone to premature failure. A design similar to that disclosed in prior art application Ser. No. 15/330,212, with a modification to allow access for maintenance to plungers, packing, suction valve, and the suction seat would provide a major and much needed improvement.
SUMMARY OF THE INVENTIONIn accordance with embodiments of the invention, a fluid end assembly with a modular fluid end housing design is disclosed. The fluid end assembly comprises a modular housing, suction manifold and multiple plungers, suction and discharge valves and seats, suction valve spring retainer/plunger spacers, staybolts, various seals, and miscellaneous components.
A modular housing of the present invention comprises a single central fluid module and multiple suction seat modules and packing box modules. The central fluid module has multiple internal cavities or fluid chambers. The modular housing assembly includes an equal number of suction seat modules and packing box modules. The number of fluid chambers equals the number of plungers in the pump. The central fluid module is bound to the power end and the suction seat modules by stayrods that pass through stayrod bores in the central fluid module. The packing boxes modules are bound and secured to the central fluid module by packing box bolts that pass through packing box bolt bores in the central module. In the prior art, packing box modules were bound to the fluid end by bolts that were threaded into the main module of the fluid end. The threads in the fluid end housing necessary to accommodate the threaded bolts resulted in high stresses in the sharp cornered thread roots. These high stresses combined with stresses at the intersection of the discharge and suction valve bores with the plunger bore resulted in cyclic fatigue and structural failure of the fluid end.
The modular design of the present invention affords several unique advantages. For example, the present disclosure provides vastly improved access for maintenance, thereby augmenting the improvements disclosed in the fluid end of U.S. Non-Provisional patent application Ser. No. 15/330,213, illustrated in
In the various embodiments of the invention, staybolt and plunger box bolt bores pass uninterrupted through the central fluid module; threads are eliminated in central fluid modules. Because of the lack of stress in the thread roots typical of packing box attachment designs of the prior art overall stress in the central fluid module is reduced and this member can be reduced in size. This size reduction results in lower manufacturing cost and lower fluid end assembly weight. The latter is critical in truck mounted pumps typical of the high pressure fracturing industry.
The central fluid module of the present invention comprises multiple fluid chambers with each chamber having a plunger bore and a discharge bore. The centerline of the plunger bore is collinear or aligned with the centerline of the suction bore of the suction seat module, commonly referred to as an “in-line configuration,” i.e., the bores and centerlines are aligned. The configuration of the suction bore of the present invention eliminates the loss of fluid energy present in fluid end housings of the prior art in which the suction fluid flow must undergo a right-angle turn to fill the fluid chamber of the housing. Inherently the packing box bore centerline is collinear with the centerline of the plunger bore centerline. The discharge port of the discharge bore in the fluid chamber of the central fluid module is required by this design to pass between two of each of the stayrod and packing box bolt bores without piercing said stayrod or packing box bolt bores. In order to contain the high pump pressure within the discharge port, the discharge port must be surrounded by sufficient wall thickness within the central fluid module to prevent structural failure of discharge port due to the high pressure contained within.
As discussed in the background of this application, a significantly large discharge and suction valve and seat are necessary to prevent erosion damage to the valve seal when pumping abrasive slurries at high volumes or pump rates. However, a large discharge valve and seat requires a large discharge port in the prior art. Notably, the prior art fails to discuss the size of the discharge port that connects the discharge valve and seat with the plunger bore in the fluid chamber of the fluid end. Because flow in the discharge port is straight and uniform without obstructions or changes of direction, the flow area of the discharge port can be significantly reduced as compared to the flow area of either the discharge or suction valve and seat. Accordingly, the flow area of the discharge port can also be reduced compared to the flow area immediately below either the discharge or suction valves and seats. The prior art fails to disclose the relationship between the discharge port and the discharge manifold. The discharge manifold must accommodate the flow of at least two (2) plungers in a triplex pumps or three (3) plungers in a quintuplex pump. Because of the staggered throws on the crankshaft, multiple discharge and suction valves and seats are open at a particular moment in the revolution or cycle of the pump crankshaft. Thus the discharge manifold must accommodate the exhaust of multiple plungers at a particular moment in time. Thus the size of the discharge port need not be any larger than 50% of the size of the discharge manifold because both the discharge port and manifold are subjected to the same flow conditions. Sizing of the discharge port based on this derivation results in a discharge port of a size significantly smaller is size of any in the prior art. In the prior art discharge ports were by default simply designed to the same size as the bottom of the taper in the fluid end housing utilized to capture the discharge seat. In the prior art, there is no disclosure of reducing the size of the discharge port to reduce stress at the intersection of the discharge and plunger bores of the fluid end housing.
In the present invention, the flow in the discharge port transitions to the larger flow area in the discharge seat via a frusto-conical volume located between the bottom of the discharge seat and the discharge port. This transitional volume reduces the flow rate of the slurry as it enters the discharge valve and seat. The disclosure of the present invention teaches a nonobvious advantage by showing that the width of the discharge port can be significantly reduced. This width is measured perpendicular to a plane formed by the centerline axis of the plunger bore and discharge bore. Reducing the width of the discharge bore, as defined above, also reduces the Bore Intersection Pitch, which also reduces the stress at the intersection of the plunger bore and the discharge port. Reducing the width of the discharge port, as defined above, allows the discharge port to pass undisturbed between the stayrod bores and plunger box bolt bores without piercing said bores and compromising the structural strength of the central fluid module.
In an alternate embodiment of this invention, the discharge port is oblong in cross section as opposed to circular. In this embodiment the width of the discharge port is unchanged from the first embodiment in which the discharge port is cylindrical; this width is measured perpendicular to a plane formed by the centerline axis of the plunger and discharge bores. This embodiment does not change the Bore Intersection Pitch or increase the stress level at the intersection of the plunger bore and the discharge port.
There is the potential of turbulence and erosion damage by a highly abrasive fracturing fluid laden with sand as the fluid is pushed out of the plunger bore into the discharge port, through the discharge valve and seat, and into the discharge manifold. Both embodiments utilize a suction valve spring retainer/plunger spacer with a sleeve or tubular section with a single port to exhaust pumped fluid from the plunger bore into the discharge port. A key feature of this invention is the sizing of the port in this sleeve section. The port is sized is be equal to or slight smaller in area than the area at the intersection of the discharge port with the plunger bore in the fluid chamber of the central fluid module. With the proper positioning, alignment, and sizing of the port in the suction valve spring retainer/plunger spacer, this member becomes a sacrificial, inexpensive, and replaceable part that can be used to absorb erosion damage and prevent premature failure of the central fluid module by structural failure due to high stress induced from the erosion damage.
The suction bore 10, located wholly within the suction seat module 1 and opposite to the packing bore 30, holds the suction seat 112. Discharge bore 20 connects with discharge manifold 50, which connects with multiple adjacent discharge bores and exhausts pumped fluid externally from the modular housing 101. Discharge bore 20 contains a discharge seat 212, discharge valve 214, discharge valve spring 215, discharge cover 216, and discharge cover retainer 217. Major internal components of the assembly 100 arranged in the packing bore 30 of packing box module 3 include plunger packing 361, and the plunger packing gland nut 351. Plunger bore 40 holds the suction valve spring retainer/plunger spacer 440, suction valve 114, suction valve spring 115, suction valve guide 458 and suction valve spring retainer 456. Suction valve guide 458 and suction valve spring retainer 456 are integral to the suction valve spring retainer/plunger spacer 440. Plunger 410 reciprocates back and forth within the sleeve section 442 of the suction valve spring retainer/plunger spacer 440, packing box module bore 30, packing 361, and packing gland nut 351.
Discharge bore 20 of the central fluid module 2 comprises a tapered discharge seat bore 22 that captures the discharge seat 212 as shown in
Tapered discharge seat bore 22 is separated from frusto-conical transition volume 23 by discharge seat taper shoulder 28 to which the bottom of discharge seat 212 contacts. Internal diameter 25 of suction seat taper shoulder 28 is coincidental with major internal diameter 25 of frusto-conical transition volume 23.
Packing box module bore 30 comprises a packing bore 32 for holding plunger packing 361 and a plunger packing gland nut bore 35 for positioning of the plunger packing gland nut 351, as illustrated in
Each fluid chamber 4 of central fluid module 2 consists of a discharge bore 20 and a plunger bore 40. Plunger bore 40 mates concentrically with suction valve spring retainer/plunger spacer 440. As illustrated in
As further illustrated in
As shown in
W-DP≤20% W-PS.
Sleeve section 442 of suction valve spring retainer/plunger spacer 440 has a substantially cylindrically inside surface 444. The diameter of cylindrical inner surface 444 is slightly greater than diameter of plunger 410 to allow plunger 410 to reciprocate freely within sleeve section 442 of suction valve spring retainer/plunger spacer 440. Substantially cylindrical exterior surface 443 of sleeve section 442 of the suction valve spring retainer/plunger spacer 440 mates with plunger bore 40 of central section 2 of modular housing 101.
Sleeve section 442 has a port 441 that aligns with port 21 in central section 2 of modular housing 101. The spring retainer section 456 is configured to position and retain the suction valve spring 115. Spring retainer section 456 connects with sleeve section 442 via multiple webs 452. Multiple ports 451 allow passage of pumped fluid from the suction valve 114 to the interior of sleeve section 442 of the suction valve spring retainer/plunger spacer 440. Valve guide 458 guides suction valve 114 between the open and closed position against seat 112. Face 447, distal from valve guide 458, shoulders against face 37 of packing box module 3 of modular housing 101. Bevel 448 at the intersection of port 441 with inside cylindrical surface 444 reduces fluid turbulence as pumped fluid exits plunger bore 40 into discharge port 21. Centerline 449 of port 441 aligns with discharge bore 20 centerline 29 of central fluid module 2. The area of port 441 is equal or slightly smaller than the area of bore intersection 42 of port 21 in central fluid module 2.
Also illustrated in
Sleeve section 442′ of suction valve spring retainer/plunger spacer 440′ has a port 441′ that aligns with port 21′ in central section 2′ of modular housing 101′. Centerline 449′ of port 441′ aligns with discharge bore 20′ centerline 29′ of central fluid module 2′. Valve guide 458, spring retainer section 456, face 447, multiple webs 452, and multiple ports 451 of suction valve spring retainer/plunger spacer 440′ are unchanged from similar sections of suction valve spring retainer/plunger spacer 440 illustrated in
Claims
1. A plunger pump fluid end comprising:
- a modular housing, wherein said housing further comprises: a central fluid module; a plurality of packing box modules; a plurality of suction seat modules; and
- a plurality of suction valve spring retainer/plunger spacers;
- a plurality of plungers and plunger packings; and
- a plurality of suction valves and seats and a plurality of discharge valves and seats;
- wherein the number of suction seat modules is equal to the number of plunger packing box modules and also is equal to the number of said plungers;
- wherein each of said central fluid modules comprises a plurality of central fluid chambers and the number of said central fluid chambers equals the number of said plungers;
- wherein each of said central fluid chambers comprises a plunger bore and a discharge bore;
- wherein centerline axes of a bore of said suction seat module and a bore of a packing box module are colinear with centerline axes of said plunger bore in each central fluid chamber;
- wherein a centerline axis of said discharge bore is perpendicular to the centerline axes of said suction bore and said plunger bore;
- wherein the number of suction valves and seats equals the number of discharge valves and seats which is also equal to the number of plungers in said fluid end;
- wherein the number of said suction valve spring retainer/plunger spacers equals the number of plungers in said fluid end; and
- wherein the area of said port in said suction valve spring retainer/plunger spacer is equal to or less than the area of the intersection of said plunger and discharge bores in said central housing.
2. A plunger pump fluid end of claim 1, wherein said discharge port in said central housing is oblong in cross section at the intersection of the plunger bore and the discharge bore and the long axis of said oblong section is parallel with the centerline axis of said plunger.
3. A plunger pump fluid end of claim 1, wherein the port in said suction valve spring retainer/plunger spacer is oblong in cross section and the long axis of said oblong section is parallel with the centerline axis of said plunger.
4. A plunger pump fluid end of claim 1, wherein a width of said discharge port, measured perpendicular to a plane formed by the centerline axis of the plunger bore and the centerline axis of the discharge bore, is smaller in width than the port in each of the suction seat module.
5. A plunger pump fluid end of claim 1, wherein a width of said discharge port, measured perpendicular to a plane formed by the centerline axis of the plunger bore and the centerline axis of the discharge bore, is 50% or less of a width of a port in each of the suction seat modules.
6. A plunger pump fluid end of claim 1, wherein a width of said discharge port, measured perpendicular to a plane formed by the centerline axis of the plunger bore and the centerline axis of the discharge bore, is less than the width of the discharge manifold in said central fluid module.
8. A plunger pump fluid end of claim 1, wherein a width of said discharge port, measured perpendicular to a plane formed by the centerline axis of the plunger bore and the centerline axis of the discharge bore, is less than 20% of a distance between the centerlines of adjacent said plunger bores.
9. A plunger pump fluid end of claim 1, wherein said discharge port is oblong in cross section at an intersection of the plunger bore and the discharge bore and a long axis of said oblong section is parallel with the centerline axis of said plunger bores.
10. A plunger pump fluid end of claim 1, wherein a minimum wall thickness between said discharge port and said stayrod bores is equal to or greater than 50% of a width of said discharge port, wherein said width is measured perpendicular to a plane formed by said centerline axis of the plunger bore and said centerline axis of the discharge bore.
Type: Application
Filed: Apr 7, 2020
Publication Date: Jul 23, 2020
Inventor: George H. Blume (Austin, TX)
Application Number: 16/842,564