ACTUATOR FOR A RECIPROCATING PUMP

TECHNICAL FIELD

This disclosure relates to reciprocating pumps, and, in particular, to actuators for reciprocating pumps.

BACKGROUND

In oilfield operations, reciprocating pumps are used for different applications such as fracturing subterranean formations to drill for oil or natural gas, cementing the wellbore, or treating the wellbore and/or formation. A reciprocating pump designed for fracturing operations is sometimes referred to as a ‘frac pump. _ A reciprocating pump typically includes a power end section and a fluid end section. The fluid end section can be formed of a one piece construction or a series of blocks secured together by rods. The fluid end section includes a fluid cylinder (sometimes referred to as a cylinder section or a fluid end block) having a plunger bore for receiving a plunger, an inlet fluid passage, and an outlet fluid passage (sometimes referred to as a discharge passage). The inlet and outlet passages each include a valve assembly to control the flow of fluid into and out of the fluid cylinder. For example, the valve assemblies can be differential pressure valves that are opened by differential pressure of fluid and allow the fluid to flow in only one direction through the corresponding inlet or outlet passage.

During operation of a reciprocating pump, rotation of a crankshaft of the power end section reciprocates the plunger within the plunger bore of the fluid end section to thereby pump fluid into the fluid cylinder through the inlet passage and out through the outlet passage. But, the crankshaft provides the plunger with a relatively short stroke length that increases the cyclical rate of the reciprocating pump. Accordingly, the valve assemblies experience a relatively large number of sealing events during operation of the reciprocating pump, which increases wear on the valve assemblies. Moreover, at least some known reciprocating pumps experience non-uniform flow rates. For example, at least some known reciprocating pumps experience flow rate surges, which for example may be undesirable during fracking operations.

SUMMARY

This summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This summary is not intended to identify key features or essential features of the claimed subject matter. Nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

In a first aspect, a reciprocating pump assembly includes a fluid end section having a pressure chamber and a plunger bore that fluidly communicates with the pressure chamber. The reciprocating pump assembly includes a plunger configured to be held within the plunger bore of the fluid end section, and a linear actuator operatively connected to the plunger such that the linear actuator is configured to reciprocate the plunger within the plunger bore during operation of the reciprocating pump to thereby pump fluid through the fluid end section.

In some embodiments, the linear actuator includes at least one of a mechanical linear actuator, an electrical linear actuator, an electro-mechanical linear actuator, a magnetic linear actuator, a hydraulic linear actuator, a pneumatic linear actuator, a screw-type actuator, a ball screw, a lead screw, a rotary screw, a screw jack, a roller screw, a hydraulic piston, a linear motor, a wheel and axle actuator, a telescoping linear actuator, a solenoid, or a servo.

In some embodiments, the reciprocating pump assembly includes a driver configured to drive operation of the linear actuator. The driver includes at least one of an engine, an electrical motor, a turbine, a hydraulic pump, a pneumatic pump, a mechanical pump, an electrical power source, an electrical circuit, a processor, a mechanical drive system, a pneumatic system, or a hydraulic system.

In some embodiments, the reciprocating pump assembly includes a power end section that includes the linear actuator.

In some embodiments, the reciprocating pump assembly includes a controller operatively connected to the linear actuator such that the controller is configured to electronically control a flow rate of fluid through the fluid end section.

In a second aspect, a reciprocating pump assembly includes a first fluid end section having a first pressure chamber and a first plunger bore that fluidly communicates with the first pressure chamber. The reciprocating pump assembly includes a first plunger rod assembly that includes a first plunger configured to be held within the first plunger bore of the first fluid end section. The reciprocating pump assembly includes a second fluid end section having a second pressure chamber and a second plunger bore that fluidly communicates with the second pressure chamber. The reciprocating pump assembly includes a second plunger rod assembly that includes a second plunger configured to be held within the second plunger bore of the second fluid end section. The reciprocating pump assembly includes at least one linear actuator operatively connected to the first and second plunger rod assemblies such that the at least one linear actuator is configured to reciprocate the first and second plungers within the first and second plunger bores, respectively, during operation of the reciprocating pump to thereby pump fluid through the first and second fluid end sections.

In some embodiments, the at least one linear actuator includes at least one of a mechanical linear actuator, an electrical linear actuator, an electro-mechanical linear actuator, a magnetic linear actuator, a hydraulic linear actuator, a pneumatic linear actuator, a screw-type actuator, a ball screw, a lead screw, a rotary screw, a screw jack, a roller screw, a hydraulic piston, a linear motor, a wheel and axle actuator, a telescoping linear actuator, a solenoid, or a servo.

In some embodiments, the reciprocating pump assembly includes at least one driver configured to drive operation of the at least one linear actuator. The driver includes at least one of an engine, an electrical motor, a turbine, a hydraulic pump, a pneumatic pump, a mechanical pump, an electrical power source, an electrical circuit, a processor, a mechanical drive system, a pneumatic system, or a hydraulic system.

In some embodiments, the reciprocating pump assembly includes a power end section that includes the at least one linear actuator.

In some embodiments, at least one of the first fluid end section includes only a single one of the first pressure chamber or the second fluid end section includes only a single one of the second pressure chamber.

In some embodiments, the first and second plunger rod assemblies are operatively connected to the at least one linear actuator such that the first and second plunger rod assemblies are coaxially aligned with each other.

In some embodiments, the at least one linear actuator is configured to simultaneously move the first and second plunger rod assemblies in the same direction.

In some embodiments, the at least one linear actuator is configured to simultaneously move the first and second plunger rod assemblies in opposite directions.

In some embodiments, the at least one linear actuator is at least one first linear actuator. The reciprocating pump assembly includes a third fluid end section having a third pressure chamber and a third plunger bore that fluidly communicates with the third pressure chamber. The reciprocating pump assembly includes a third plunger rod assembly that includes a third plunger configured to be held within the third plunger bore of the third fluid end section. The reciprocating pump assembly includes a fourth fluid end section having a fourth pressure chamber and a fourth plunger bore that fluidly communicates with the fourth pressure chamber. The reciprocating pump assembly includes a fourth plunger rod assembly that includes a fourth plunger configured to be held within the fourth plunger bore of the fourth fluid end section. The reciprocating pump assembly includes at least one second linear actuator operatively connected to the third and fourth plunger rod assemblies such that the at least one second linear actuator is configured to reciprocate the third and fourth plungers within the third and fourth plunger bores, respectively, during operation of the reciprocating pump to thereby pump fluid through the third and fourth fluid end sections.

In some embodiments, the reciprocating pump assembly includes a controller operatively connected to the at least one linear actuator such that the controller is configured to electronically control a flow rate of fluid through the first and second fluid end sections.

In a third aspect, a method for operating a reciprocating pump assembly includes operatively connecting at least one linear actuator to a first plunger rod assembly of a first fluid end section having a first plunger bore; operatively connecting the at least one linear actuator to a second plunger rod assembly of a second fluid end section having a second plunger bore; and reciprocating respective first and second plungers of the first and second plunger rod assemblies within the first and second plunger bores, respectively, using the at least one linear actuator to pump fluid through the first and second fluid end sections.

In some embodiments, reciprocating the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator includes simultaneously moving the first and second plunger rod assemblies in the same direction.

In some embodiments, reciprocating the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator includes electronically controlling a flow rate of fluid through the first and second fluid end sections.

In some embodiments, the at least one linear actuator is at least one first linear actuator. The method further includes operatively connecting at least one second linear actuator to a third plunger rod assembly of a third fluid end section having a third plunger bore; operatively connecting the at least one second linear actuator to a fourth plunger rod assembly of a fourth fluid end section having a fourth plunger bore; reciprocating respective third and fourth plungers of the third and fourth plunger rod assemblies within the third and fourth plunger bores, respectively, using the at least one second linear actuator to pump fluid through the third and fourth fluid end sections; and offsetting the duty cycle of the first and second fluid end sections from the duty cycle of the third and fourth fluid end sections.

Other aspects, features, and advantages will become apparent from the following detailed description when taken in conjunction with the accompanying drawings, which are a part of this disclosure and which illustrate, by way of example, principles of the inventions disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings facilitate an understanding of the various embodiments.

FIG. 1 is an elevational view of a reciprocating pump assembly according to an exemplary embodiment.

FIG. 2 is a cross-sectional view of a fluid end section of the reciprocating pump assembly shown in FIG. 1 according an exemplary embodiment.

FIG. 3 is an elevational view illustrating a plurality of the reciprocating pump assemblies shown in FIG. 1 combined together according to an exemplary embodiment.

FIG. 4 illustrates a chart showing the combined and individual flow rates of multiple reciprocating pump assemblies according to an exemplary embodiment.

FIG. 5 illustrates a chart showing the combined and individual flow rates of multiple reciprocating pump assemblies according to an exemplary embodiment.

FIG. 6 illustrates a chart showing the combined and individual flow rates of multiple reciprocating pump assemblies according to an exemplary embodiment.

FIG. 7 illustrates a chart showing the combined and individual flow rates of multiple reciprocating pump assemblies according to an exemplary embodiment.

FIG. 8 is a flowchart illustrating a method for operating a reciprocating pump assembly according to an exemplary embodiment.

Corresponding reference characters indicate corresponding parts throughout the drawings.

DETAILED DESCRIPTION

Certain embodiments of the disclosure provide a reciprocating pump assembly that includes a fluid end section having a pressure chamber and a plunger bore that fluidly communicates with the pressure chamber. The reciprocating pump assembly includes a plunger configured to be held within the plunger bore of the fluid end section, and a linear actuator operatively connected to the plunger such that the linear actuator is configured to reciprocate the plunger within the plunger bore during operation of the reciprocating pump to thereby pump fluid through the fluid end section.

Certain embodiments of the disclosure provide a reciprocating pump assembly includes a first fluid end section having a first pressure chamber and a first plunger bore that fluidly communicates with the first pressure chamber. The reciprocating pump assembly includes a first plunger rod assembly that includes a first plunger configured to be held within the first plunger bore of the first fluid end section. The reciprocating pump assembly includes a second fluid end section having a second pressure chamber and a second plunger bore that fluidly communicates with the second pressure chamber. The reciprocating pump assembly includes a second plunger rod assembly that includes a second plunger configured to be held within the second plunger bore of the second fluid end section. The reciprocating pump assembly includes at least one linear actuator operatively connected to the first and second plunger rod assemblies such that the at least one linear actuator is configured to reciprocate the first and second plungers within the first and second plunger bores, respectively, during operation of the reciprocating pump to thereby pump fluid through the first and second fluid end sections.

Certain embodiments of the disclosure provide a method for operating a reciprocating pump assembly includes operatively connecting at least one linear actuator to a first plunger rod assembly of a first fluid end section having a first plunger bore; operatively connecting the at least one linear actuator to a second plunger rod assembly of a second fluid end section having a second plunger bore; and reciprocating respective first and second plungers of the first and second plunger rod assemblies within the first and second plunger bores, respectively, using the at least one linear actuator to pump fluid through the first and second fluid end sections.

Certain embodiments of the disclosure increase the stroke length of the plunger of the fluid end section of a reciprocating pump assembly and thereby reduce the number of sealing events experienced by valve assemblies of the fluid end section during operation of the reciprocating pump assembly. Certain embodiments of the disclosure increase the longevity of the valve assemblies of a fluid end section of a reciprocating pump assembly and thereby reduce the operating costs of a reciprocating pump assembly. Certain embodiments of the disclosure provide a relatively steady flow of fluid (e.g., a relatively uniform flow rate, a relatively constant flow rate, a relatively consistent flow rate, etc.) through a fluid end section of a reciprocating pump assembly. Certain embodiments of the disclosure may reduce flow rate surges of a reciprocating pump assembly.

Referring to FIG. 1, an illustrative embodiment of a reciprocating pump assembly 100 is presented. The reciprocating pump assembly 100 includes a power end section 102 and a pair of fluid end sections 104 operably coupled thereto. Specifically, the reciprocating pump assembly 100 includes a fluid end section 104a operably coupled to the power end section 102 and a fluid end section 104b operably coupled to the power end section 102. The power end section 102 includes a housing 106 in which a linear actuator 120 is disposed. Each of the fluid end sections 104a and 104b includes a fluid cylinder 108 (sometimes referred to as a ‘fluid end block_ or a ‘cylinder section_), which in the exemplary embodiments is connected to the housing 106 via a plurality of stay rods 110a, 110b, 110c, and 110d. Other structures may be used to connect the fluid end section 104 to the housing 106 in addition or alternatively to the stay rods 110a, 110b, 110c, and/or 110d.

The linear actuator 120 is operatively connected to plungers 114 of the plunger rod assemblies 112. Specifically, the linear actuator 120 is operatively connected to a plunger 114a of a plunger rod assembly 112a via a plunger rod 113a; and the linear actuator 120 is operatively connected to a plunger 114b of a plunger rod assembly 112b via a plunger rod 113b. In operation, the linear actuator 120 reciprocates plunger rod assemblies 112 between the power end section 102 and the fluid end sections 104a and 104b to thereby pump (i.e., move) fluid through the fluid cylinders 108 of the fluid end sections 104a and 104b, as will be described in more detail below.

According to some embodiments, the reciprocating pump assembly 100 is freestanding on the ground, mounted to a trailer for towing between operational sites, mounted to a skid, loaded on a manifold, otherwise transported, and/or the like. The reciprocating pump assembly 100 is not limited to frac pumps. Rather, the embodiments disclosed herein may be used with any other type of pump that includes a plunger rod assembly.

FIG. 2 illustrates one of the fluid end sections 104 (e.g., the fluid end section 104a, the fluid end section 104b, etc.) of the reciprocating pump assembly 100 according to an exemplary embodiment. Referring now to FIG. 2, the fluid cylinder 108 of the fluid end section 104 includes a pressure chamber 118 and a plunger bore 116 that fluidly communicates with the pressure chamber 118. The plunger 114 of the plunger rod assembly 112 is held within (e.g., extends through, etc.) the plunger bore 116 such that the plunger 114 extends into the pressure chamber 118. At least the plunger bore 116, the pressure chamber 118, and the plunger 114 together may be characterized as a ‘plunger throw._ According to some embodiments, the reciprocating pump assembly 100 includes three plunger throws (i.e., a triplex pump assembly); however, in other embodiments, the reciprocating pump assembly 100 includes a greater or fewer number of plunger throws (e.g., only a single plunger throw, etc.).

As shown in FIG. 2, the fluid cylinder 108 includes inlet and outlet fluid passages 120 and 122, respectively, formed therein. Optionally, the inlet and outlet fluid passages 120 and 122, respectively, are coaxially disposed along a fluid passage axis 124, for example as is shown in FIG. 2. Fluid is adapted to flow through the inlet and outlet fluid passages 120 and 122, respectively, and along the fluid passage axis 124. An inlet valve assembly 126 is disposed in the inlet fluid passage 120 and an outlet valve assembly 128 is disposed in the outlet fluid passage 122. In the exemplary embodiments, the valve assemblies 126 and 128 are spring-loaded, which, as described in greater detail below, are actuated by at least a predetermined differential pressure across each of the valve assemblies 126 and 128.

The inlet valve assembly 126 includes a valve seat 130 and a valve member 132 that is configured to be sealingly engaged therewith. The valve seat 130 includes an inlet valve bore 134 that extends along a valve seat axis 136 that is coaxial with the fluid passage axis 124 when the inlet valve assembly 126 is disposed in the inlet fluid passage 120. The valve seat 130 further includes a shoulder 138, which in the exemplary embodiment is tapered (i.e., extends at an oblique angle relative to the valve seat axis 136). In some other examples, the shoulder 138 of the valve seat 130 extends approximately perpendicular to the valve seat axis 136.

The valve member 132 includes a valve head 142 and a tail segment 140 extending from the valve head 142. As shown in FIG. 2, the tail segment 140 is received within the inlet valve bore 134 of the valve seat 130 when the inlet valve assembly 126 is assembled as shown. The valve head 142 includes a seal 144. The valve head 142 of the valve member 132 is moveable relative to the valve seat 130 along the valve seat axis 136 between an open position and a closed position. In the closed position of the valve member 132, the seal 144 of the valve head 142 sealingly engages the valve seat 130 to prevent fluid flow through the inlet valve assembly 126. In the exemplary embodiments, the valve member 132 is engaged and otherwise biased by a spring 146, which, as discussed in greater detail below, biases the valve member 132 to the closed position.

According to certain embodiments, at least a portion of the valve seat 130 and/or at least a portion of the valve head 142 is formed from stainless steel. But, the valve seat 130 and/or the valve head 142 may be formed from any other material in addition or alternative to stainless steel. Although shown herein as being a helical (i.e., coil) compression spring, additionally or alternatively the spring 146 can include any type of spring, such as, but not limited to, a flat spring, a machined spring, a serpentine spring, a torsion spring, a tension spring, a constant spring, a variable spring, a variable stiffness spring, a leaf spring, a cantilever spring, a volute spring, a v-spring, and/or the like.

In the embodiments illustrated herein, the outlet valve assembly 128 is substantially similar to the inlet valve assembly 126 and therefore will not be described in further detail herein.

In operation, the plunger 114 reciprocates within the plunger bore 116 for movement into and out of the pressure chamber 118. That is, the plunger 114 moves back and forth horizontally, as viewed in FIG. 2, away from and towards the fluid passage axis 124. As will be described below, the linear actuator 120 (FIG. 1) moves the plunger 114 toward and away from the fluid passage axis 124. Movement of the plunger 114 in the direction of arrow 148 away from the fluid passage axis 124 and out of the pressure chamber 118 will be referred to herein as the suction stroke of the plunger 114. As the plunger 114 moves along the suction stroke, the inlet valve assembly 126 is opened to the open position of the valve member 132. More particularly, as the plunger 114 moves away from the fluid passage axis 124 in the direction of arrow 148, the pressure inside the pressure chamber 118 decreases, creating a differential pressure across the inlet valve assembly 126 and causing the valve head 142 of the valve member 132 to move (relative to the valve seat 130) upward, as viewed in FIG. 2, along the valve seat axis 136 in the direction of arrow 150. As a result of the upward movement of the valve head 142 of the valve member 132 along the valve seat axis 136, the spring 146 is compressed and the valve head 142 of the valve member 132 separates from the shoulder 138 of the valve seat 130 to move the valve member 132 to the open position. In the open position of the valve member 132, fluid entering through an inlet 152 of the inlet fluid passage 120 flows along the fluid passage axis 124 and through the inlet valve assembly 126, being drawn into the pressure chamber 118. To flow through the inlet valve assembly 126, the fluid flows through the inlet valve bore 134 and along the valve seat axis 136. The inlet 152 defines a suction port of the fluid end section 104.

During the fluid flow through the inlet valve assembly 126 and into the pressure chamber 118, the outlet valve assembly 128 is in a closed position wherein a seal 154 of a valve member 156 of the outlet valve assembly 128 is sealingly engaged with a shoulder 158 of a valve seat 160 of the outlet valve assembly 128. Fluid continues to be drawn into the pressure chamber 118 until the plunger 114 is at the end of the suction stroke of the plunger 114, wherein the plunger 114 is at the farthest point from the fluid passage axis 124 of the range of motion of the plunger 114.

At the end of the suction stroke of the plunger 114, the differential pressure across the inlet valve assembly 126 is such that the spring 146 of the inlet valve assembly 126 begins to decompress and extend, forcing the valve head 142 of the valve member 132 of the inlet valve assembly 126 to move (relative to the valve seat 130) downward, as viewed in FIG. 2, along the valve seat axis 136 in the direction of arrow 162. As a result, the inlet valve assembly 126 moves to the closed position of the valve member 132 wherein the valve head 142 of the valve member 132 is sealingly engaged with the valve seat 130.

Movement of the plunger 114 in the direction of arrow 164 toward the fluid passage axis 124 and into the pressure chamber 118 will be referred to herein as the discharge stroke of the plunger 114. As the plunger 114 moves along the discharge stroke into the pressure chamber 118, the pressure within the pressure chamber 118 increases. The pressure within the pressure chamber 118 increases until the differential pressure across the outlet valve assembly 128 exceeds a predetermined set point, at which point the outlet valve assembly 128 opens and permits fluid to flow out of the pressure chamber 118 along the fluid passage axis 124, being discharged through an outlet 165 of the fluid end section 104. During the discharge stroke of the plunger 114, the valve member 132 of the inlet valve assembly 126 is positioned in the closed position wherein the valve head 142 of the valve member 132 is sealingly engaged with the valve seat 130. The outlet 165 of the fluid end section 104 defines a discharge port of the fluid end section 104.

The fluid cylinder 108 of the fluid end section 104 of the reciprocating pump assembly 100 includes an access port 166. The access port 166 is defined by an opening that extends through a body 168 of the fluid cylinder 108 to provide access to the pressure chamber 118 and thereby internal components of the fluid cylinder 108 (e.g., the inlet valve assembly 126, the outlet valve assembly 128, the plunger 114, etc.) for service (e.g., maintenance, replacement, etc.) thereof. The access port 166 of the fluid cylinder 108 is closed using a suction cover assembly 170 to seal the pressure chamber 118 of the fluid cylinder 108 at the access port 166.

The plunger bore 116 is defined by an inner wall 172 of the body 168 of the fluid cylinder 108. In other words, the plunger bore 116 includes the inner wall 172. As shown in FIG. 2, the plunger bore 116 includes a packing segment 174. The plunger rod assembly 112 includes packing 176 that is received within the packing segment 174 of the plunger bore 116 such that the packing 176 extends radially between the plunger 114 and the inner wall 172 to facilitate sealing the plunger 114 within the plunger bore 116 of the fluid cylinder 108.

The illustrated fluid end section 104 is but one example of a fluid end section that may be operably coupled to the power end section 102 (FIG. 1) of the reciprocating pump assembly 100. Other fluid end sections may additionally or alternatively be used. For example, the fluid end section 104 shown in FIG. 2 includes only a single one of the pressure chamber 118. In other embodiments, one or more of the fluid end sections disclosed herein includes two or more pressure chambers such that the fluid end section(s) provides a manifold having multiple suction and discharge ports.

Referring again to FIG. 1, and as briefly described above, the linear actuator 120 is operatively connected to the plunger 114a of the plunger rod assembly 112a via the plunger rod 113a such that the linear actuator 120 is configured to reciprocate the plunger 114a within the plunger bore 116 (FIG. 2) of the fluid end section 104a during operation of the reciprocating pump assembly 100 to thereby pump fluid through the fluid end section 104a. Specifically, the linear actuator 120 is configured to move the plunger rod 113a along an axis 178 in two opposite directions 180 and 182 toward and away, respectively, from the fluid end section 104a, as is shown in FIG. 1. Accordingly, the linear actuator 120 is configured to move the plunger 114a along the axis 178 in the opposite directions 180 and 182 to thereby reciprocate the plunger 114a within the plunger bore 116 along the axis 178. Movement of the plunger 114a along the axis 178 in the direction 182 draws fluid into a suction port 152a of the fluid end section 104a, while movement of the plunger 114a along the axis 178 in the direction 180 discharges fluid through a discharge port 165a of the fluid end section 104a. Accordingly, the linear actuator 120 is configured to pump fluid through the fluid end section 104a by reciprocating the plunger 114a within the plunger bore 116 of the fluid end section 104a.

As is also briefly described above, the linear actuator 120 is operatively connected to the plunger 114b of the plunger rod assembly 112b via the plunger rod 113b such that the linear actuator 120 is configured to reciprocate the plunger 114b within the plunger bore 116 of the fluid end section 104b during operation of the reciprocating pump assembly 100 to thereby pump fluid through the fluid end section 104b. Specifically, the linear actuator 120 is configured to move the plunger rod 113b along an axis 184 in two opposite directions 164 and 148 toward and away, respectively, from the fluid end section 104b. The linear actuator 120 thus is configured to move the plunger 114b along the axis 184 in the opposite directions 148 and 164 to thereby reciprocate the plunger 114b within the plunger bore 116 along the axis 184. Movement of the plunger 114b along the axis 184 in the direction 148 draws fluid into a suction port 152b of the fluid end section 104a, while movement of the plunger 114b along the axis 184 in the direction 164 discharges fluid through a discharge port 165b of the fluid end section 104b. Accordingly, the linear actuator 120 is configured to pump fluid through the fluid end section 104b by reciprocating the plunger 114b within the plunger bore 116 of the fluid end section 104b.

In the exemplary embodiment, the axes 178 and 184 are aligned with each other such that the plunger rod assemblies 112a and 112b are coaxially aligned with each other. In other embodiments, the axes 178 are not aligned with each other such that the plunger rod assemblies 112a and 112b are not coaxially aligned. Moreover, the exemplary embodiment illustrates an embodiment wherein the linear actuator 120: (1) moves the plunger rod assembly 112a in the direction 182 to draw fluid into the fluid end section 104a while simultaneously moving the plunger rod assembly 112b in the direction 164 to discharge fluid from the fluid end section 104b; and (2) moves the plunger rod assembly 112a in the direction 180 to discharge fluid from the fluid end section 104a while simultaneously moving the plunger rod assembly 112b in the direction 148 to draw fluid into the fluid end section 104b. In other words, in the exemplary embodiment the linear actuator 120 simultaneously moves the plunger rod assemblies 112a and 112b in the same direction. In other embodiments, the linear actuator 120 simultaneously moves the plunger rod assemblies 112a and 112b in opposite directions (i.e., the plunger rod assemblies 112a and 112b are moved in reciprocal synchronization). Specifically, in some other embodiments, the linear actuator 120: (1) moves the plunger rod assembly 112a in the direction 182 to draw fluid into the fluid end section 104a while simultaneously moving the plunger rod assembly 112b in the direction 148 to draw fluid into the fluid end section 104b; and (2) moves the plunger rod assembly 112a in the direction 180 to discharge fluid from the fluid end section 104a while simultaneously moving the plunger rod assembly 112b in the direction 164 to discharge fluid from the fluid end section 104b.

Although the exemplary embodiment illustrates a single linear actuator 120 that moves both the plunger rod assembly 112a and the plunger rod assembly 112b, other embodiments may include two or more linear actuators 120. For example, the reciprocating pump assembly 100 may include a first linear actuator 120 that is operatively connected to the plunger rod assembly 112a for reciprocating the plunger 114a within the plunger bore 116 of the fluid end section 104a and a second linear actuator 120 that is operatively connected to the plunger rod assembly 112b for reciprocating the plunger 114b within the plunger bore 116 of the fluid end section 104b. In another example, the reciprocating pump assembly 100 includes a first linear actuator 120 that is operatively connected to the plunger rod assemblies 112a and 112b for moving the plungers 114a and 114b in the respective directions 182 and 164 and a second linear actuator 120 that is operatively connected to the plunger rod assemblies 112a and 112b for moving the plungers 114a and 114b in the respective directions 180 and 148.

In the exemplary embodiment, the linear actuator 120 is housed within the housing 106 of the power end section 102 of the reciprocating pump assembly 100 such that the power end section 102 includes the linear actuator 120. But, the linear actuator 120 additionally or alternatively may be: (1) housed within the fluid end section 104a; (2) housed within the fluid end section 104b; and/or (3) positioned external to the power end section 102, the fluid end section 104a, and/or the fluid end section 104b.

Each linear actuator 120 may include any type of linear actuator, such as, but not limited to, a mechanical linear actuator, an electrical linear actuator, an electro-mechanical linear actuator, a magnetic linear actuator, a hydraulic linear actuator, a pneumatic linear actuator, a screw-type actuator, a ball screw, a lead screw, a rotary screw, a screw jack, a roller screw, a hydraulic piston, a linear motor, a wheel and axle actuator, a telescoping linear actuator, a solenoid, and/or a servo.

In some embodiments, an actuator driver 122 is operatively connected to the linear actuator 120 for controlling and/or driving (e.g., powering, etc.) operation of the linear actuator 120. The actuator driver 122 may include any type of driver, such as, but not limited to, an engine, an electrical motor, a turbine, a hydraulic pump (e.g., hydrostatic, hydrodynamic, etc.), a pneumatic pump, a mechanical pump, an electrical power source, an electrical circuit, an electro-mechanical drive system, an electric pump, a magnetic drive system, a processor, a mechanical drive system, a pneumatic drive system, a hydraulic drive system, software (e.g., computer-executable instructions stored on a non-transitory computer-storage memory and executed by one or more processors, such as, but not limited to, a local processor, a remote processor, and/or the like, etc.), and/or the like.

The linear actuator 120 disclosed herein may enable the stroke length of the plungers 114a and 114b to be increased, for example as compared to at least some known reciprocating pump assemblies that utilize one or more crankshafts to reciprocate a plunger within a fluid end section. Moreover, the linear actuator 120 disclosed herein may enable the reciprocating pump assembly to provide a relatively steady flow of fluid (e.g., a relatively uniform flow rate, a relatively constant flow rate, a relatively consistent flow rate, etc.) through the fluid end sections 104a and 104b. For example, the action of reciprocating the plungers 114 within the plunger bores 116 completes pumping cycles in which fluid is discharged from a first of the fluid end sections (e.g., the fluid end section 104a or 104b, etc.) while also drawn into a second of the fluid end sections (e.g., the fluid end section 104a or 104b, etc.) and then discharged out of the second fluid end section while also drawn into the first fluid end section. Such pumping cycles can be continuously (or at least repeatedly) performed to create a relatively steady flow rate of fluid from the reciprocating pump assembly 100 (e.g., for fracking operations, etc.), which for example may reduce flow rate surges of the reciprocating pump assembly 100. In some embodiments, a controller (not shown in FIG. 1; e.g., the controller 200 shown in FIG. 3, etc.) is provided (e.g., as a component of the actuator driver 122, etc.) that operatively connected to the linear actuator 120 such that the controller is configured to electronically control a flow rate of fluid through the fluid end sections 104a and 104b.

In some embodiments, two or more of the reciprocating pump assemblies 100 can be combined, for example to facilitate providing a steady flow of fluid. For example, and referring now to FIG. 3, multiple reciprocating pump assemblies 100a-n are combined together such that linear actuators 120a-n thereof control fluid being pumped into and out of fluid end sections 104 thereof, for example in a manner that produces a relatively steady flow rate of fluid. In some embodiments, failure of a linear actuator 120 and/or another component of a reciprocating pump assembly 100 (e.g., the reciprocating pump assembly 100a, the reciprocating pump assembly 100n, etc.) may be compensated for by one or more of the other reciprocating pump assemblies 100 (e.g., the reciprocating pump assembly 100a, the reciprocating pump assembly 100n, etc.). While only two reciprocating pump assemblies 100a and 100n are shown, any number may be used, for example two, three, four, five, six, seven, eight, nine, or ten or more reciprocating pump assemblies 100.

In some embodiments, a controller 200 is operatively connected to the linear actuators 120a-n such that the controller 200 is configured to synchronize the various reciprocating pump assemblies 100 to draw and discharge fluid, for example either synchronously and/or at different times that are offset from each other. For example, the controller 200 may be configured to offset the duty cycle of the fluid end sections 104a and 104b from the duty cycle of the fluid end sections 104c and 104d shown in FIG. 3. Specifically, and for example, combining multiple reciprocating pump assemblies 100 as is shown in FIG. 3 may enable an operator to offset the linear actuation of plunger rod assemblies 112a, 112b, 112c, and/or 112d, and thus the plungers 114a, 114b, 114c, and/or 114d in such a way that causes discharging of fluid from each reciprocating pump assembly 100a and 100n at optimal times, for example to produces a relatively steady flow of fluid (e.g., distributed to well operations, etc.). Examples of timing offsets for multiple reciprocating pump assemblies 100 include, but are not limited to, an offset by one-half of the duty cycle between two or more reciprocating pump assemblies 100, an offset by one-third of the duty cycle between two or more reciprocating pump assemblies 100, an offset by one-quarter of the duty cycle between two or more reciprocating pump assemblies 100, and/or the like.

The controller 200 may be any type of controller, such as, but not limited to, a mechanical controller, an electrical controller, an electro-mechanical controller, a software controller, and/or the like.

FIG. 4 illustrates a chart 300 showing the combined and individual flow rates of multiple reciprocating pump assemblies 100 with two different banks of three cylinders, according to some embodiments. The following charts illustrate additional pumping details for such a configuration. The embodiment illustrated in FIG. 4 depicts no delay (or offset) between the various reciprocating pump assemblies 100.

Multi Cylinders with Trapezoidal flow rate curves, Haversine ramp

Cycle
Time
Total
Cyl 1
Cyl 2
Cyl 3
Cyl 4
Cyl 5
Cyl 6

0.000
0.000
144.585
0.000
28.917
28.917
28.917
28.917
28.917

0.021
0.138
144.585
1.101
27.816
28.917
28.917
28.917
28.917

0.042
0.275
144.585
4.235
24.682
28.917
28.917
28.917
28.917

0.063
0.413
144.585
8.925
19.991
28.917
28.917
28.917
28.917

0.083
0.550
144.585
14.458
14.458
28.917
28.917
28.917
28.917

0.104
0.688
144.585
19.991
8.925
28.917
28.917
28.917
28.917

0.125
0.825
144.585
24.682
4.235
28.917
28.917
28.917
28.917

0.146
0.963
144.585
27.816
1.101
28.917
28.917
28.917
28.917

0.167
1.100
144.585
28.917
0.000
28.917
28.917
28.917
28.917

0.188
1.238
144.585
28.917
1.101
27.816
28.917
28.917
28.917

0.208
1.375
144.585
28.917
4.235
24.682
28.917
28.917
28.917

0.229
1.513
144.585
28.917
8.925
19.991
28.917
28.917
28.917

0.250
1.650
144.585
28.917
14.458
14.458
28.917
28.917
28.917

0.271
1.788
144.585
28.917
19.991
8.925
28.917
28.917
28.917

0.292
1.925
144.585
28.917
24.682
4.235
28.917
28.917
28.917

0.313
2.063
144.585
28.917
27.816
1.101
28.917
28.917
28.917

0.333
2.200
144.585
28.917
28.917
0.000
28.917
28.917
28.917

0.354
2.338
144.585
28.917
28.917
1.101
27.816
28.917
28.917

0.375
2.475
144.585
28.917
28.917
4.235
24.682
28.917
28.917

0.396
2.613
144.585
28.917
28.917
8.925
19.991
28.917
28.917

0.417
2.750
144.585
28.917
28.917
14.458
14.458
28.917
28.917

0.438
2.888
144.585
28.917
28.917
19.991
8.925
28.917
28.917

0.458
3.025
144.585
28.917
28.917
24.682
4.235
28.917
28.917

0.479
3.163
144.585
28.917
28.917
27.816
1.101
28.917
28.917

0.500
3.300
144.585
28.917
28.917
28.917
0.000
28.917
28.917

0.521
3.438
144.585
28.917
28.917
28.917
1.101
27.816
28.917

0.542
3.575
144.585
28.917
28.917
28.917
4.235
24.682
28.917

0.563
3.713
144.585
28.917
28.917
28.917
8.925
19.991
28.917

0.583
3.850
144.585
28.917
28.917
28.917
14.458
14.458
28.917

0.604
3.988
144.585
28.917
28.917
28.917
19.991
8.925
28.917

0.625
4.125
144.585
28.917
28.917
28.917
24.682
4.235
28.917

0.646
4.263
144.585
28.917
28.917
28.917
27.816
1.101
28.917

0.667
4.400
144.585
28.917
28.917
28.917
28.917
0.000
28.917

0.688
4.538
144.585
28.917
28.917
28.917
28.917
1.101
27.816

0.708
4.675
144.585
28.917
28.917
28.917
28.917
4.235
24.682

0.729
4.813
144.585
28.917
28.917
28.917
28.917
8.925
19.991

0.750
4.950
144.585
28.917
28.917
28.917
28.917
14.458
14.458

0.771
5.088
144.585
28.917
28.917
28.917
28.917
19.991
8.925

0.792
5.225
144.585
28.917
28.917
28.917
28.917
24.682
4.235

0.813
5.363
144.585
28.917
28.917
28.917
28.917
27.816
1.101

0.833
5.500
144.585
28.917
28.917
28.917
28.917
28.917
0.000

0.854
5.638
144.585
27.816
28.917
28.917
28.917
28.917
1.101

0.875
5.775
144.585
24.682
28.917
28.917
28.917
28.917
4.235

0.896
5.913
144.585
19.991
28.917
28.917
28.917
28.917
8.925

0.917
6.050
144.585
14.458
28.917
28.917
28.917
28.917
14.458

0.938
6.188
144.585
8.925
28.917
28.917
28.917
28.917
19.991

0.958
6.325
144.585
4.235
28.917
28.917
28.917
28.917
24.682

0.979
6.463
144.585
1.101
28.917
28.917
28.917
28.917
27.816

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

1.000
6.600
144.585
0.000
28.917
28.917
28.917
28.917
28.917

Hydraulic Horsepower Table 10 in stroke

4.5 in plunger 12 kpsi pressure

Cylinders that determine Profile

263
2
3
4
5
6
7
8
9

text missing or illegible when filed

1
263
263
263
263
263
263
263
263

2
526
526
526
526
526
526
526
526

3
789
789
789
789
789
789
789
789

4
1052
1052
1052
1052
1052
1052
1052
1052

5
1314
1314
1314
1314
1314
1314
1314
1314

6
1577
1577
1577
1577
1577
1577
1577
1577

7
1840
1840
1840
1840
1840
1840
1840
1840

8
2103
2103
2103
2103
2103
2103
2103
2103

9
2366
2366
2366
2366
2366
2366
2366
2366

text missing or illegible when filed

indicates data missing or illegible when filed

Number of Cylinders C
6
0.833333

Multiple of synched Cylinders
1

Stroke
10
in

Ramp Time t_r
1.1
sec

Plunger Diameter
4.5
in

Intensifier Ratio
3
:1

Job Pressure
12000
psi

Dwell Time t_d
4.4

Maximum Pressure
15000
psi

T
6.6
sec

Cylinder Rod Length
42
in

Cylinder Rod Modulus
2.90E+07
psi

Min Cylinder Rod diameter
4.00
in

Actual Cylinder Rod diameter
4.50
in

Cylinder Piston Diameter
9.00
in

Job Cylinder Pressure
4000
psi

Stroke Volume per stroke per
159
in³

cylinder

Volume rate per cylinder
28.91693
in³/sec

Volume rate all cylinders
144.5847
in³/sec

A for Plunger
28.91693
in³/sec

A for Hydraulic Piston
86.7508
in³/sec

Rod Load
190851.8
lbf

Max Rod Load
238564.7
lbf

FIG. 5 illustrates a chart 400 showing the combined and individual flow rates of multiple reciprocating pump assemblies 100 with two different banks of three cylinders, according to some embodiments. The following charts illustrate additional pumping details for such a configuration. The embodiment of FIG. 5 depicts a ramp-up delay (or offset) between the various reciprocating pump assemblies 100.

Multi Cylinders with Trapezoidal flow rate curves, Haversine ramp

Cycle
Time
Total
Cyl 1
Cyl 2
Cyl 3
Cyl 4
Cyl 5
Cyl 6

0.000
0.000
144.585
0.000
0.000
36.146
36.146
36.146
36.146

0.021
0.138
144.585
1.376
0.000
34.770
36.146
36.146
36.146

0.042
0.275
144.585
5.293
0.000
30.853
36.146
36.146
36.146

0.063
0.413
144.585
11.157
0.000
24.989
36.146
36.146
36.146

0.083
0.550
144.585
18.073
0.000
18.073
36.146
36.146
36.146

0.104
0.688
144.585
24.989
0.000
11.157
36.146
36.146
36.146

0.125
0.825
144.585
30.853
0.000
5.293
36.146
36.146
36.146

0.146
0.963
144.585
34.770
0.000
1.376
36.146
36.146
36.146

0.167
1.100
144.585
36.146
0.000
0.000
36.146
36.146
36.146

0.188
1.238
144.585
36.146
1.376
0.000
34.770
36.146
36.146

0.208
1.375
144.585
36.146
5.293
0.000
30.853
36.146
36.146

0.229
1.513
144.585
36.146
11.157
0.000
24.989
36.146
36.146

0.250
1.650
144.585
36.146
18.073
0.000
18.073
36.146
36.146

0.271
1.788
144.585
36.146
24.989
0.000
11.157
36.146
36.146

0.292
1.925
144.585
36.146
30.853
0.000
5.293
36.146
36.146

0.313
2.063
144.585
36.146
34.770
0.000
1.376
36.146
36.146

0.333
2.200
144.585
36.146
36.146
0.000
0.000
36.146
36.146

0.354
2.338
144.585
36.146
36.146
1.376
0.000
34.770
36.146

0.375
2.475
144.585
36.146
36.146
5.293
0.000
30.853
36.146

0.396
2.613
144.585
36.146
36.146
11.157
0.000
24.989
36.146

0.417
2.750
144.585
36.146
36.146
18.073
0.000
18.073
36.146

0.438
2.888
144.585
36.146
36.146
24.989
0.000
11.157
36.146

0.458
3.025
144.585
36.146
36.146
30.853
0.000
5.293
36.146

0.479
3.163
144.585
36.146
36.146
34.770
0.000
1.376
36.146

0.500
3.300
144.585
36.146
36.146
36.146
0.000
0.000
36.146

0.521
3.438
144.585
36.146
36.146
36.146
1.376
0.000
34.770

0.542
3.575
144.585
36.146
36.146
36.146
5.293
0.000
30.853

0.563
3.713
144.585
36.146
36.146
36.146
11.157
0.000
24.989

0.583
3.850
144.585
36.146
36.146
36.146
18.073
0.000
18.073

0.604
3.988
144.585
36.146
36.146
36.146
24.989
0.000
11.157

0.625
4.125
144.585
36.146
36.146
36.146
30.853
0.000
5.293

0.646
4.263
144.585
36.146
36.146
36.146
34.770
0.000
1.376

0.667
4.400
144.585
36.146
36.146
36.146
36.146
0.000
0.000

0.688
4.538
144.585
34.770
36.146
36.146
36.146
1.376
0.000

0.708
4.675
144.585
30.853
36.146
36.146
36.146
5.293
0.000

0.729
4.813
144.585
24.989
36.146
36.146
36.146
11.157
0.000

0.750
4.950
144.585
18.073
36.146
36.146
36.146
18.073
0.000

0.771
5.088
144.585
11.157
36.146
36.146
36.146
24.989
0.000

0.792
5.225
144.585
5.293
36.146
36.146
36.146
30.853
0.000

0.813
5.363
144.585
1.376
36.146
36.146
36.146
34.770
0.000

0.833
5.500
144.585
0.000
36.146
36.146
36.146
36.146
0.000

0.854
5.638
144.585
0.000
34.770
36.146
36.146
36.146
1.376

0.875
5.775
144.585
0.000
30.853
36.146
36.146
36.146
5.293

0.896
5.913
144.585
0.000
24.989
36.146
36.146
36.146
11.157

0.917
6.050
144.585
0.000
18.073
36.146
36.146
36.146
18.073

0.938
6.188
144.585
0.000
11.157
36.146
36.146
36.146
24.989

0.958
6.325
144.585
0.000
5.293
36.146
36.146
36.146
30.853

0.979
6.463
144.585
0.000
1.376
36.146
36.146
36.146
34.770

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

1.000
6.600
144.585
0.000
0.000
36.146
36.146
36.146
36.146

Number of Cylinders C
6
0.833333

Multiple of synched Cylinders
1

Stroke
10
in
2.272727

Ramp Time t_r
1.1
sec
Matzner

Plunger Diameter
4.5
in

Intensifier Ratio
3
:1

Job Pressure
12000
psi

Dwell Time t_d
3.3

Maximum Pressure
15000
psi

T
6.6
sec

Cylinder Rod Length
42
in

Cylinder Rod Modulus
2.90E+07
psi
Alternate

Min Cylinder Rod diameter
4.00
in

Actual Cylinder Rod diameter
4.50
in

Cylinder Piston Diameter
9.00
in

Job Cylinder Pressure
4000
psi

Stroke Volume per stroke per
159
in³
0.69

cylinder

Volume rate per cylinder
36.14617
in³/sec
9.388614

Volume rate all cylinders
144.5847
in³/sec
37.55446

A for Plunger
36.14617
in³/sec
1.818182

A for Hydraulic Piston
108.4385
in³/sec
2.272727

Rod Load
190851.8
lbf

Max Rod Load
238564.7
lbf

FIG. 6 illustrates a chart 500 showing the combined and individual flow rates of multiple reciprocating pump assemblies 100 with two different banks of three cylinders, according to some embodiments. The following charts illustrate additional pumping details for such a configuration. The embodiment of FIG. 6 depicts a half overlap between different sets of the reciprocating pump assemblies 100.

Multi Cylinders with Trapezoidal flow rate curves, Haversine ramp

Cycle
Time
Total
Cyl 1
Cyl 2
Cyl 3
Cyl 4
Cyl 5
Cyl 6

0.000
0.000
289.169
0.000
0.000
0.000
72.292
144.585
72.292

0.042
0.138
289.169
5.503
0.000
0.000
44.627
139.082
99.957

0.083
0.275
289.169
21.174
0.000
0.000
21.174
123.411
123.411

0.125
0.413
289.169
44.627
0.000
0.000
5.503
99.957
139.082

0.167
0.550
289.169
72.292
0.000
0.000
0.000
72.292
144.585

0.208
0.688
289.169
99.957
5.503
0.000
0.000
44.627
139.082

0.250
0.825
289.169
123.411
21.174
0.000
0.000
21.174
123.411

0.292
0.963
289.169
139.082
44.627
0.000
0.000
5.503
99.957

0.333
1.100
289.169
144.585
72.292
0.000
0.000
0.000
72.292

0.375
1.238
289.169
139.082
99.957
5.503
0.000
0.000
44.627

0.417
1.375
289.169
123.411
123.411
21.174
0.000
0.000
21.174

0.458
1.513
289.169
99.957
139.082
44.627
0.000
0.000
5.503

0.500
1.650
289.169
72.292
144.585
72.292
0.000
0.000
0.000

0.542
1.788
289.169
44.627
139.082
99.957
5.503
0.000
0.000

0.583
1.925
289.169
21.174
123.411
123.411
21.174
0.000
0.000

0.625
2.063
289.169
5.503
99.957
139.082
44.627
0.000
0.000

0.667
2.200
289.169
0.000
72.292
144.585
72.292
0.000
0.000

0.708
2.338
289.169
0.000
44.627
139.082
99.957
5.503
0.000

0.750
2.475
289.169
0.000
21.174
123.411
123.411
21.174
0.000

0.792
2.613
289.169
0.000
5.503
99.957
139.082
44.627
0.000

0.833
2.750
289.169
0.000
0.000
72.292
144.585
72.292
0.000

0.875
2.888
289.169
0.000
0.000
44.627
139.082
99.957
5.503

0.917
3.025
289.169
0.000
0.000
21.174
123.411
123.411
21.174

0.958
3.163
289.169
0.000
0.000
5.503
99.957
139.082
44.627

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
0.000
72.292
144.585
72.292

1.000
3.300
289.169
0.000
0.000
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72.292

FIG. 7 illustrates a chart 600 showing the combined and individual flow rates of multiple reciprocating pump assemblies 100 with two different banks of three cylinders, according to some embodiments. The following chart illustrates additional pumping details for such a configuration. The embodiment of FIG. 7 depicts a quarter overlap between different sets of the reciprocating pump assemblies 100.

Number of Cylinders C
3
0.666667

Multiple of synched Cylinders
1

Stroke
10
in

Ramp Time t_r
1.1
sec

Plunger Diameter
4.5
in

Intensifier Ratio
3
:1

Job Pressure
12000
psi

Dwell Time t_d
0

Maximum Pressure
15000
psi

T
3.3
sec

Cylinder Rod Length
42
in

Cylinder Rod Modulus
2.90E+07
psi

Min Cylinder Rod diameter
4.00
in

Actual Cylinder Rod diameter
4.50
in

Cylinder Piston Diameter
9.00
in

Job Cylinder Pressure
4000
psi

Stroke Volume per stroke per
159
in³

cylinder

Volume rate per cylinder
144.5847
in³/sec

Volume rate all cylinders
144.5847
in³/sec

A for Plunger
144.5847
in³/sec

A for Hydraulic Piston
433.754
in³/sec

Rod Load
190851.8
lbf

Max Rod Load
238564.7
lbf

FIG. 8 is a flowchart illustrating a method 700 for operating a reciprocating pump assembly according to an exemplary embodiment. The method 700 includes operatively connecting, at 702, at least one linear actuator to a first plunger rod assembly of a first fluid end section having a first plunger bore. At 704, the method 700 includes operatively connecting the at least one linear actuator to a second plunger rod assembly of a second fluid end section having a second plunger bore. At 706, the method 700 includes reciprocating respective first and second plungers of the first and second plunger rod assemblies within the first and second plunger bores, respectively, using the at least one linear actuator to pump fluid through the first and second fluid end sections.

In some embodiments, reciprocating at 706 the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator includes simultaneously moving, at 706a, the first and second plunger rod assemblies in the same direction. Reciprocating at 706 the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator includes electronically controlling, at 706b, a flow rate of fluid through the first and second fluid end sections in some embodiments.

Optionally, the at least one linear actuator is at least one first linear actuator and the method 700 further includes: operatively connecting, at 708, at least one second linear actuator to a third plunger rod assembly of a third fluid end section having a third plunger bore; operatively connecting, at 710, the at least one second linear actuator to a fourth plunger rod assembly of a fourth fluid end section having a fourth plunger bore; reciprocating, at 712, respective third and fourth plungers of the third and fourth plunger rod assemblies within the third and fourth plunger bores, respectively, using the at least one second linear actuator to pump fluid through the third and fourth fluid end sections; and offsetting, at 714, the duty cycle of the first and second fluid end sections from the duty cycle of the third and fourth fluid end sections.

Various embodiments disclosed herein increase the stroke length of the plunger of the fluid end section of a reciprocating pump assembly and thereby reduce the number of sealing events experienced by valve assemblies of the fluid end section during operation of the reciprocating pump assembly. Various embodiments disclosed herein increase the longevity of the valve assemblies of a fluid end section of a reciprocating pump assembly and thereby reduce the operating costs of a reciprocating pump assembly. Various embodiments disclosed herein provide a relatively steady flow of fluid (e.g., a relatively uniform flow rate, a relatively constant flow rate, a relatively consistent flow rate, etc.) through a fluid end section of a reciprocating pump assembly. Various embodiments disclosed herein may reduce flow rate surges of a reciprocating pump assembly.

The following clauses describe further aspects of the disclosure:

Clause Set A:

A1. A reciprocating pump assembly comprising:

a fluid end section having a pressure chamber and a plunger bore that fluidly communicates with the pressure chamber;

a plunger configured to be held within the plunger bore of the fluid end section; and

a linear actuator operatively connected to the plunger such that the linear actuator is configured to reciprocate the plunger within the plunger bore during operation of the reciprocating pump to thereby pump fluid through the fluid end section.

A2. The reciprocating pump assembly of clause Al, wherein the linear actuator comprises at least one of a mechanical linear actuator, an electrical linear actuator, an electro-mechanical linear actuator, a magnetic linear actuator, a hydraulic linear actuator, a pneumatic linear actuator, a screw-type actuator, a ball screw, a lead screw, a rotary screw, a screw jack, a roller screw, a hydraulic piston, a linear motor, a wheel and axle actuator, a telescoping linear actuator, a solenoid, or a servo.

A3. The reciprocating pump assembly of clause Al, further comprising a driver configured to drive operation of the linear actuator, the driver comprising at least one of an engine, an electrical motor, a turbine, a hydraulic pump, a pneumatic pump, a mechanical pump, an electrical power source, an electrical circuit, a processor, a mechanical drive system, a pneumatic system, or a hydraulic system.

A4. The reciprocating pump assembly of clause Al, further comprising a power end section that comprises the linear actuator.

A5. The reciprocating pump assembly of clause Al, further comprising a controller operatively connected to the linear actuator such that the controller is configured to electronically control a flow rate of fluid through the fluid end section. Clause Set B:

B1. A reciprocating pump assembly comprising:

a first fluid end section having a first pressure chamber and a first plunger bore that fluidly communicates with the first pressure chamber;

a first plunger rod assembly comprising a first plunger configured to be held within the first plunger bore of the first fluid end section;

a second fluid end section having a second pressure chamber and a second plunger bore that fluidly communicates with the second pressure chamber;

a second plunger rod assembly comprising a second plunger configured to be held within the second plunger bore of the second fluid end section; and

at least one linear actuator operatively connected to the first and second plunger rod assemblies such that the at least one linear actuator is configured to reciprocate the first and second plungers within the first and second plunger bores, respectively, during operation of the reciprocating pump to thereby pump fluid through the first and second fluid end sections.

B2. The reciprocating pump assembly of clause B1, wherein the at least one linear actuator comprises at least one of a mechanical linear actuator, an electrical linear actuator, an electro-mechanical linear actuator, a magnetic linear actuator, a hydraulic linear actuator, a pneumatic linear actuator, a screw-type actuator, a ball screw, a lead screw, a rotary screw, a screw jack, a roller screw, a hydraulic piston, a linear motor, a wheel and axle actuator, a telescoping linear actuator, a solenoid, or a servo.

B3. The reciprocating pump assembly of clause B1, further comprising at least one driver configured to drive operation of the at least one linear actuator, the driver comprising at least one of an engine, an electrical motor, a turbine, a hydraulic pump, a pneumatic pump, a mechanical pump, an electrical power source, an electrical circuit, a processor, a mechanical drive system, a pneumatic system, or a hydraulic system.

B4. The reciprocating pump assembly of clause B1, further comprising a power end section that comprises the at least one linear actuator. B5. The reciprocating pump assembly of clause B1, wherein at least one of the first fluid end section includes only a single one of the first pressure chamber or the second fluid end section includes only a single one of the second pressure chamber.

B6. The reciprocating pump assembly of clause B1, wherein the first and second plunger rod assemblies are operatively connected to the at least one linear actuator such that the first and second plunger rod assemblies are coaxially aligned with each other.

B7. The reciprocating pump assembly of clause B1, wherein the at least one linear actuator is configured to simultaneously move the first and second plunger rod assemblies in the same direction.

B8. The reciprocating pump assembly of clause B1, wherein the at least one linear actuator is configured to simultaneously move the first and second plunger rod assemblies in opposite directions.

B9. The reciprocating pump assembly of clause B1, wherein the at least one linear actuator is at least one first linear actuator, the reciprocating pump assembly further comprising:

a third fluid end section having a third pressure chamber and a third plunger bore that fluidly communicates with the third pressure chamber;

a third plunger rod assembly comprising a third plunger configured to be held within the third plunger bore of the third fluid end section;

a fourth fluid end section having a fourth pressure chamber and a fourth plunger bore that fluidly communicates with the fourth pressure chamber;

a fourth plunger rod assembly comprising a fourth plunger configured to be held within the fourth plunger bore of the fourth fluid end section; and

at least one second linear actuator operatively connected to the third and fourth plunger rod assemblies such that the at least one second linear actuator is configured to reciprocate the third and fourth plungers within the third and fourth plunger bores, respectively, during operation of the reciprocating pump to thereby pump fluid through the third and fourth fluid end sections.

B10. The reciprocating pump assembly of clause B1, further comprising a controller operatively connected to the at least one linear actuator such that the controller is configured to electronically control a flow rate of fluid through the first and second fluid end sections.

B11. The reciprocating pump assembly of clause B1, wherein the at least one linear actuator is at least one first linear actuator, the reciprocating pump assembly further comprising:

a third fluid end section having a third pressure chamber and a third plunger bore that fluidly communicates with the third pressure chamber;

a third plunger rod assembly comprising a third plunger configured to be held within the third plunger bore of the third fluid end section;

a fourth fluid end section having a fourth pressure chamber and a fourth plunger bore that fluidly communicates with the fourth pressure chamber;

a fourth plunger rod assembly comprising a fourth plunger configured to be held within the fourth plunger bore of the fourth fluid end section;

a controller operatively connected to the at least one first linear actuator and the at least one second linear actuator such that the controller is configured to offset the duty cycle of the first and second fluid end sections from the duty cycle of the third and fourth fluid end sections.

Clause Set C:

C1. A method for operating a reciprocating pump assembly comprising:

operatively connecting at least one linear actuator to a first plunger rod assembly of a first fluid end section having a first plunger bore;

operatively connecting the at least one linear actuator to a second plunger rod assembly of a second fluid end section having a second plunger bore; and

reciprocating respective first and second plungers of the first and second plunger rod assemblies within the first and second plunger bores, respectively, using the at least one linear actuator to pump fluid through the first and second fluid end sections.

C2. The method of clause C1, wherein reciprocating the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator comprises simultaneously moving the first and second plunger rod assemblies in the same direction.

C3. The method of clause C1, wherein reciprocating the first and second plungers within the first and second plunger bores, respectively, using the at least one linear actuator comprises electronically controlling a flow rate of fluid through the first and second fluid end sections.

C4. The method of clause C1, wherein the at least one linear actuator is at least one first linear actuator, the method further comprising:

operatively connecting at least one second linear actuator to a third plunger rod assembly of a third fluid end section having a third plunger bore;

operatively connecting the at least one second linear actuator to a fourth plunger rod assembly of a fourth fluid end section having a fourth plunger bore;

reciprocating respective third and fourth plungers of the third and fourth plunger rod assemblies within the third and fourth plunger bores, respectively, using the at least one second linear actuator to pump fluid through the third and fourth fluid end sections; and

offsetting the duty cycle of the first and second fluid end sections from the duty cycle of the third and fourth fluid end sections.

It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. Furthermore, invention(s) have been described in connection with what are presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention(s). Further, each independent feature or component of any given assembly may constitute an additional embodiment. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from its scope. Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the disclosure should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled.

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 ‘clockwise_ and ‘counterclockwise_, ‘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.

When introducing elements of aspects of the disclosure or the examples thereof, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. For example, 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_, ‘comprises_, ‘having_, ‘has_, includes_, and ‘including_ where they appear. Further, references to “one embodiment” are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features. Moreover, unless explicitly stated to the contrary, embodiments “comprising” or “having” an element or a plurality of elements having a particular property can include additional elements not having that property. The term ‘exemplary_ is intended to mean ‘an example of._ The phrase ‘one or more of the following: A, B, and C_ means ‘at least one of A and/or at least one of B and/or at least one of C.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means-plus-function format and are not intended to be interpreted based on 35 U.S.C. § 112(f), unless and until such claim limitations expressly use the phrase ‘means for_ followed by a statement of function void of further structure.

Although the terms ‘step_ and/or ‘block_ may be used herein to connote different elements of methods employed, the terms should not be interpreted as implying any particular order among or between various steps herein disclosed unless and except when the order of individual steps is explicitly described. The order of execution or performance of the operations in examples of the disclosure illustrated and described herein is not essential, unless otherwise specified. The operations may be performed in any order, unless otherwise specified, and examples of the disclosure may include additional or fewer operations than those disclosed herein. It is therefore contemplated that executing or performing a particular operation before, contemporaneously with, or after another operation is within the scope of aspects of the disclosure.

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.

	Number	Date	Country
	62719478	Aug 2018	US
	62753677	Oct 2018	US

ACTUATOR FOR A RECIPROCATING PUMP

Information

Publication Number

Date Filed

Date Published

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CPC

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Abstract

Description

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CROSS-REFERNCE TO RELATED APPLICATION

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Provisional Applications (2)