Patent Application
20250207574
In certain embodiments, the present disclosure is directed towards an apparatus comprising a plunger assembly. The plunger assembly is configured to reciprocate in a plunger bore formed within a fluid end body. The plunger assembly comprises a plunger body, a valve seat, and a valve assembly. The plunger body has a first end, a second end, and a first bore interconnecting the first and second ends. The valve seat is situated within the plunger body adjacent the first end. The valve assembly is positioned adjacent the first end of the plunger body. The valve assembly comprises a valve body configured to engage the valve seat, a retainer installed within the first bore, a stem, and a spring. The stem has a first end connected to the valve body and an opposed second end. The retainer rotates with the stem and is free to move axially along the stem. The spring is concentric with the stem and is installed within the first bore. The spring is situated between the retainer and the second end of the stem.
In another aspect, certain embodiments of the present disclosure are directed towards an apparatus comprising a fluid end body, a plunger, a valve assembly, a conduit, and an inlet manifold. The fluid end body comprises a plunger bore. The plunger is configured to reciprocate within the plunger bore. The plunger comprises a first end, an opposed second end, a first opening formed in the first end, a second opening formed in the second end, a fluid bore extending inside the plunger and joining the first and second openings, and a valve seat installed in the plunger adjacent the second opening. The valve assembly comprises a valve body configured to seal against the valve seat. The conduit has opposed first and second ends. The first end is attached to the first end of the plunger via an inlet component. The inlet manifold and second end of the inlet conduit are situated above the first end of the fluid end conduit and the plunger.
U.S. Pat. No. 11,578,710 (hereinafter referred to as “the '710 patent”), entitled ‘Fracturing Pump with In-Line Fluid End’, issued on Feb. 14, 2023, is incorporated herein by reference in its entirety.
Various hydraulic pumps having fluid ends are commonly used in industrial applications to deliver high volumes of highly pressurized fluids during operations such as hydraulic fracturing (“fracking”). Some of these hydraulic pumps, as well as their benefits, are described in detail in the '710 patent.
This patent application describes an apparatus that improves prior high-pressure pumps in a variety of ways. The application describes various embodiments of a fluid end, as well as various methods of assembling, maintaining, operating, and repairing the fluid end.
Looking particularly to the pump described in the '710 patent, the “in-line” nature of the fluid end pump eliminates the need for intersecting bores, thus reducing the likelihood of stress and fatigue failures while increasing fluid end operational life. While this “in-line” pump technology is presented in the '710 patent, this patent application describes further innovative improvements in features and designs to the “in-line” pump. These features are described in detail herein.
One of these improvements is the introduction of a sleeve within the fluid end's plunger, which improves installation of a valve assembly. The sleeve is sized such that its orientation and geometry enable a user to at least partially compress the spring of the valve assembly while installing the valve assembly in the plunger. Further, instead of machining this profile into the inner diameter of the bore of the plunger, the sleeve provides a removable component that can be machined separate from the plunger and removed or replaced if needed. Thus, the sleeve, among other advantages, also provides an easier manufacturing process of the improved designs disclosed herein.
Another improvement within certain embodiments disclosed herein is a split “static” section of the fluid end. The split static section is divided into two pieces, which reduces the risk of cutting or harming dynamic seals during initial installation of “dynamic” sections into the static section. During construction of the fluid end, dynamic sections are threaded into a first piece of the static section, then essentially pushed straight into dynamic seals such that the dynamic seals surround at least a portion of the dynamic sections. The two static pieces are then combined, and the dynamic sections are further torqued into the combined static section as needed. By eliminating the step of rotating the dynamic sections directly into the dynamic seals, the risk of harming the dynamic seals is reduced. The installation and construction of the static and dynamic sections are described more herein.
Other improvements discussed herein include the addition of hardened inserts in areas subject to high erosion, such as surfaces that engage seals. The addition of hardened inserts reduces wear and erosion, which in turn increases the life of the parts in which such inserts are installed in.
Yet another improvement discussed herein is the introduction of a twist-on “locking” retainer. This retainer may be replaced with a bolt-on design, as desired. Both designs offer improved efficiencies in installing, replacing, and removing components of the fluid end.
In some embodiments, a packing sleeve may be inserted into a dynamic section or piece. Such packing sleeve may not have a hardened insert within; however, it should be noted that hardened inserts formed of carbide or other hard materials may be used in the sealing area between the packing sleeve and the dynamic section, and/or the sealing area between the packing sleeve and the packing.
In general, a fluid is routed through the fluid end by passing through a suction conduit, then into a plunger's internal bore. The fluid may then pass through a valve installed at one end of the plunger and into a cavity. The plunger may then extend into the cavity such that the fluid is pressurized. Once pressurized, the fluid may then pass through another valve, and out of a discharge port or conduit. The proceeding description should be understood to be a general example and overview of how the fluid end operates, and should not be misunderstood to be limiting in any way. There may be many ways to operate the fluid end described herein.
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The dynamic section mounting bores 141 are through bores connecting the front 143 and rear 144 surfaces of the rear static section 114. Each dynamic section mounting bore 141 has an internal thread 145 configured to receive a dynamic section 102. When the static section 101 is assembled, the locations of the dynamic section mounting bores 141 align with the flow bores 125 of the front static section 113 on a one-to-one basis. The bore axes of the dynamic section mounting bores 141 are also collinear with the bore axes of the flow bores 125 on a one-to-one basis.
The rear static section mounting holes 142 are through bores connecting the front 143 and rear 144 surfaces of the rear static section 114. Each rear static section mounting hole 142 has a counterbore opening to the rear surface 144 of the rear static section 114. When the static section 101 is assembled, the locations of the rear static section mounting holes 142 align with the rear static section mounting holes 126 of the front static section 113 on a one-to-one basis. The bore axes of the rear static section mounting holes 142 are also collinear with the bore axes of the rear static section mounting holes 126 of the front static section 113.
Referring now to
The retainer flange section 150 comprises a plurality of cutouts 154. In this embodiment there are two cutouts 154, however there may be more if desired. Since the diameter of the retainer flange section 150 of the through bore 149 is smaller than that of the dynamic flange section 151, the cutouts 154 only modify the retainer flange section 150. Radially, each cutout 154 removes the entire portion of the retainer 103 from the through bore 149 radially outward to the intermediate outer surface 148, leaving a radial wall 155 at the radial limits of each cutout 154, that is two for each cutout 154. Longitudinally, the cutout 154 begins at the front surface 146, continues through the entire length of the retainer flange section 150 and ends within the dynamic flange section 151, leaving a cutout surface 156 at the longitudinal limit of each cutout 154.
The dynamic flange section 151 of the through bore 149 has a larger diameter than each adjacent section, thus creating a front shoulder 157 and rear shoulder 158. The rear shoulder 158 further comprises a seal groove 159.
The packing nut section 153 comprises an internal thread 160 originating at the rear surface 147 of the retainer 103. The packing nut section 153 further comprises a thread relief 161 adjacent the packing section 152 and the internal thread 160.
The retainer 103 further comprises a lubrication port 162 connecting the intermediate outer surface 148 to the packing section 152 of the through bore 149. The lubrication port 162 may have internal threads 163 and/or a counterbore 164 configured to accept a lubrication fitting (not shown) as needed.
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The intermediate outer surface 170 also has areas with different features. Beginning at the front surface 168 and continuing to the rear surface 169, each intermediate outer surface 170 comprises a dynamic seal section 176, an external thread 177, a retainer flange relief section 178, and a dynamic flange section 179. The retainer flange relief section 178 has a smaller diameter than dynamic flange section 179, thus forming a rear shoulder 180 as part of the retainer flange relief section 178, as shown in
The dynamic flange section 179 comprises a plurality of cutouts 1136. In this embodiment, there are two cutouts 1136 to match the number of cutouts 154 in the retainer 103. Since the diameter of the dynamic flange section 179 is larger than that of the retainer flange relief section 178, the cutouts 1136 only modify the dynamic flange section 179. Radially, each cutout 1136 removes only a portion of the dynamic flange section 179 from the intermediate outer surface 170 down, that is radially, toward the longitudinal axis of the dynamic section body 165, but not all the way through to the through bore 171. The cutouts 1136 thus form a radial wall 1137 at the radial limits of each cutout 1136, that is two for each cutout 1136. Longitudinally, the cutout 1136 begins at the rear surface 169 and continues through the entire length of the dynamic flange section 179. The radial depth of the cutouts 1136 is such that the rear shoulder 180 height is reduced, but the rear shoulder 180 is not eliminated. The cutouts 1136 also form a cutout surface 1138 that is the radial base of the cutout 1136 with a diameter smaller than the diameter of the dynamic flange section 179.
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The discharge plug 122 further comprises a threaded tool bore 192 centered on the front surface 181.
The discharge plug 122 further comprises a blind valve stem bore 193 centered on and originating from the rear surface 182 and extending along the longitudinal axis to a depth coinciding with the approximate longitudinal position of the assembly clearance section 186 on the intermediate outer surface 183. The valve stem bore 193 may have a countersink 196 to facilitate assembly of the discharge valve 120 if desired.
The discharge plug 122 further comprises a plurality of relief bores 194 connecting the relief bore shoulder 188 to the valve stem bore 193. The relief bores 194 help alleviate accumulation and build-up of particulates and proppants within the valve stem bore 193. In this embodiment, there are six relief bores 194 spaced evenly circumferentially, but there may be more or less spaced intermittently if desired. Each relief bore 194 is angled from the longitudinal axis of the discharge plug 122 such that the relief bore 194 intersects the valve stem bore 193 adjacent the base 195 of the valve stem bore 193. The angle of the relief bore 194 may be adjusted as necessary depending on the spatial relationship between the relief bore shoulder 188 and the base 195 of the valve stem bore 193.
The discharge plug 122 further comprises a dowel pin bore 197. The dowel pin bore 197 is perpendicular to and intersects the longitudinal axis of the discharge plug 122. The dowel pin bore 197 is longitudinally positioned such that it intersects the intermediate outer surface 183 in the spring section 191. The dowel pin bore 197 also intersects the valve stem bore 193. The dowel pin bore 197 may have a countersink 198 to facilitate the insertion of the dowel pin 123.
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The suction valve assembly 1183 comprises a valve body 1184, a valve retention system 1122, and a valve return system 1185. The suction valve seat 1120 may be formed of a hardened material such as tungsten carbide. Such material resists wear and erosion, significantly extending the life of the suction valve seat 1120.
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The valve body 1184 has opposed front and rear surfaces 1186 and 1187. A sealing surface 1188 is formed at the rear surface 1187 of the valve body 1184 that corresponds with a tapered front surface 1189 of the suction valve seat 1120. A socket connection 1190 is formed on the front surface 1186 of the valve body 1184.
The valve retention system 1122 comprises an elongate stem 1191 installed within a retainer 1192. The retainer 1192 comprises a central support 1193 joined to two tabs 1194. The central support 1193 has a length that allows the central support 1193 to engage the rear surface 1187 of the valve body 1184. The stem 1191 has a square cross-section that corresponds to a central passage 1195 formed in the central support 1193 also having a square cross-section. The stem 1191 is thus installed within the central passage 1195. The square cross-sections prevent the stem 1191 from rotating when the valve assembly 1183 is installed within the plunger 1119. A first end 1196 of the stem 1191 is attached to the valve body 1184, while an opposed second end 1197 of the stem 1191 is attached to a valve return system 1185.
The valve return system 1185 comprises a spring stop 1198, a spring 1199, and a retainer pin 1200. The spring 1199 is disposed around the second end 1197 of the stem 1191 and the spring stop 1198 is attached to the second end 1197 of the stem 1191 via the retainer pin 1200. The spring 1199 is thus situated on the stem 1191 between the spring stop 1198 and the central support 1193 of the retainer 1192. When the suction valve assembly 1183 is assembled, the retainer 1192 rotates with the stem 1191, but is free to move longitudinally along the stem 1191. The valve body 1184 and the stem 1191 may be formed as a single, integrally formed piece, as shown in the Figures.
The valve retention system 1122 is held within the plunger 1119 using the sleeve 1121. The sleeve 1121 is sized to fit within the plunger 1119 rearward of the suction valve seat 1120, in the sleeve counterbore 1129. The sleeve 1121 may be press-fit or interference fit within the plunger 1119. Preferably, the sleeve 1121 is lightly press-fit into the plunger 1119 and is held in place by the tightly press-fitted suction valve seat 1120. The sleeve 1121 is tubular with opposed end surfaces and comprises opposed openings 1201 formed in the walls of the sleeve 1121. Each opening 1201 includes an installation slot 1202 and a relief notch 1203, as shown in
To install the valve retention system 1122 within the plunger 1119, the valve retention system 1122 is inserted into the plunger 1119 and the sleeve 1121 such that each tab 1194 passes through a corresponding one of the installation slots 1202. Once a tab 1194 is within the corresponding opening 1201, the valve retention system 1122 is rotated relative to the sleeve 1121 until each tab 1194 is forced into one of the corresponding one of the relief notches 1203. The valve retention system 1122 may be turned or rotated using a tool (not shown) installed within the socket connection 1190 formed in the valve body 1184.
The valve retention system 1122 is configured such that the spring 1199 of the valve return system 1185 is always at least partially compressed between the retainer 1192 and the spring stop 1198 of the valve return system 1185. When the valve retention system 1122 is installed within the sleeve 1121, the spring 1199 is further compressed as the tabs 1194 rotate within the corresponding openings 1201. Once the tabs 1194 are forced into the corresponding relief notches 1203, the spring 1199 is still compressed and exerts a force against the bottom of the retainer 1192, thereby holding the tabs 1194 within the corresponding relief notches 1203 and retaining the suction valve assembly 1183 within the sleeve 1121 and the plunger 1119. During operation, the stem 1191 and valve body 1184 move relative to the retainer 1192, the sleeve 1121, and the plunger 1119.
Referring now to
Fourth, the protruding dynamic seal sections 176 are aligned with the dynamic seals 115 already installed in the front static section 113, and the front surface 143 of the rear static section 114 is abutted to the rear surface 129 of the front static section 113 while simultaneously inserting the dynamic seal sections 176 into the dynamic seals 115, as shown in
Eighth, the front surface 146 of a retainer 103 and the rear surface 169 of a dynamic section body 165 are oriented to face each other and the through bores 149 and 171 are aligned to be concentric, as shown in
Twelfth, a retainer lock 105 is oriented and positioned such that the front surface 1139 faces and nearly abuts the rear surface 144 of the rear static section 114, as shown in
Sixteenth, the packing stack 106 is inserted into the now aligned through bores 149, 171 of the retainer 103 and dynamic section 102, as shown in
Twentieth, the insert section 1111 of the riser section 1108 of the top plunger suction fitting 110 is inserted into the suction fitting bore 1134 of the plunger 1119 with the flow relief notch 1112 oriented toward the front of the plunger 1119 until the internal profile 1115 of the clamp section 1109 abuts the suction fitting section 1132 of the intermediate outer surface 1125 of the plunger 1119, as shown in
Twenty-second, the internal profile 1118 of the bottom plunger suction fitting 111 is abutted to the suction fitting section 1132 of the intermediate outer surface 1125 of the plunger 1119, as shown in
Twenty-fifth, the dowel pin 123 is inserted into the dowel pin bore 197 through the dowel slot 1107, as shown in
Assembly steps eight through twenty-eight may be repeated for each flow bore 125, preferably in the same manner. The assembly of the fluid end 100 is now complete and may be mounted to a power end using stay rods similar to those in the '710 patent. After mounting to a power end, suction conduits (not shown) may be attached to the external threads 1110 of the riser sections 1108 of the top plunger fittings 110, and discharge conduits (not shown) may be attached to discharge fittings (not shown) installed in the discharge bore 127.
During assembly, the two-piece static section 101 eliminates the need rotate the dynamic section 102 as it is being inserted into the dynamic seal 115 longitudinally, that is by threading. Instead, the dynamic section 102 may be inserted into the dynamic seal 115 only along the longitudinal axis, thus reducing the chances of cutting a dynamic seal 115. If desired, the advantages given by the two-piece static section 101 may be forfeited by using a one-piece static section. Use of a one-piece static section will not negate the advantages provided by the other novel features described herein.
The use of inverse cutouts 154 and 1136 in the retainer 103 and dynamic section 102 greatly reduce assembly and disassembly time which is particularly helpful during field maintenance.
In operation, stress concentrations due to the presence of intersecting bores have been eliminated along with the intersecting bores. This increases the life of the fluid end 100.
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The intermediate outer surface 270 also has areas with different features. Beginning at the front surface 268 and continuing to the rear surface 269, each intermediate outer surface 270 comprises a dynamic seal section 276, an external thread 277, a retainer flange relief section 278, and a dynamic flange section 279. The retainer flange relief section 278 has a smaller diameter than dynamic flange section 279, thus forming a rear shoulder 280 as part of the retainer flange relief section 278, as shown in
The dynamic flange section 279 comprises a plurality of cutouts 2136. In this embodiment, there are two cutouts 2136 to match the number of cutouts 254 in the retainer flange section 250 of retainer 203. Since the diameter of the dynamic flange section 279 is larger than that of the retainer flange relief section 278, the cutouts 2136 only modify the dynamic flange section 279. Radially, each cutout 2136 removes only a portion of the dynamic flange section 279 from the intermediate outer surface 270 down, that is radially, toward the longitudinal axis of the dynamic section body 265 but not all the way through to the through bore 271. The cutouts 2136 thus form a radial wall 2137 at the radial limits of each cutout 2136, that is two for each cutout 2136. Longitudinally, the cutout 2136 begins at the rear surface 269 and continues through the entire length of the dynamic flange section 279. The radial depth of the cutouts 2136 is such that the rear shoulder 280 height is reduced but the rear shoulder 280 is not eliminated. The cutouts 2136 also form a cutout surface 2138 that is the radial base of the cutout 2136 with a diameter smaller than the diameter of the dynamic flange section 279.
Referring now to
The intermediate outer surface 2156 comprises a packing sleeve seal section 2161 and a dynamic flange section 2162. The packing sleeve seal section 2161 has a smaller diameter than dynamic flange section 2162, thus forming a dynamic flange shoulder 2163, as shown in
The dynamic flange section 2162 comprises a plurality of cutouts 2164. In this embodiment, there are two cutouts 2164 to match the number of cutouts 254 in the retainer 203. Since the diameter of the dynamic flange section 2162 is larger than that of the packing sleeve seal section 2161, the cutouts 2164 only modify the dynamic flange section 2162. Radially, each cutout 2164 removes only a portion of the dynamic flange section 2162 from the intermediate outer surface 2156 down, that is radially, toward the longitudinal axis of the packing sleeve 2150 but not all the way through to the through bore 2157. The cutouts 2164 thus form a radial wall 2165 at the radial limits of each cutout 2164, that is two for each cutout 2164. Longitudinally, the cutout 2164 begins at the rear surface 2155 and continues through the entire length of the dynamic flange section 2162. The radial depth of the cutouts 2164 is such that the dynamic flange shoulder 2163 height is reduced, but the dynamic flange shoulder 2163 is not eliminated. The cutouts 2164 also form a cutout surface 2166 that is the radial base of the cutout 2164 with a diameter smaller than the diameter of the dynamic flange section 2162. Once assembled, the cutouts 2164 longitudinally extend the cutouts 2136 of the dynamic section body 265.
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Second, the dynamic sections 202 are assembled by pressing the discharge valve seats 266 into the discharge valve seat sections 272 of the through bores 271 of each dynamic section body 265 and installing the packing sleeve seals 2151 in the packing seal sleeve grooves 2153 of the packing sleeve sections 2152 of the through bores 271, as shown in
Third, each dynamic section 202 is threaded into the rear static section 214, as shown in
Fourth, the rear static section 214 is attached to the front static section 213 and assembled dynamic seals 215 using static section connectors 216, as shown in
Fifth, the packing sleeve seal section 2161 of the intermediate outer surface 2156 of a packing sleeve 2150 is aligned with the through bore 271 of a dynamic section body 265 and inserted into the packing sleeve section 2152 until the dynamic flange shoulder 2163 abuts the rear surface 269 of the dynamic section body 265, as shown in
Sixth, the packing sleeve 2150 is rotated until the radial walls 2165 of the packing sleeve 2150 align with the radial walls 2137 of the dynamic section body 265 such that cutouts 2136 and 2164 align, as shown in
Seventh, a retainer seal 204 is inserted into the seal groove 259 in the rear shoulder 258 of a retainer 203, as shown in
Eighth, the front surface 246 of the retainer 203 and the rear surface 2155 of the packing sleeve 2150 are oriented to face each other, and the through bores 249 and 2157 are aligned to be concentric, as shown in
Ninth, the retainer 203 is oriented rotationally such that the cutouts 254 of the retainer 203 align with the non-cutout sections of the packing sleeve 2150 and dynamic section 202. Also, the cutouts 2136 and 2164 of the dynamic section 202 and packing sleeve 2150 align with the non-cutout sections of the retainer 203, as shown in
Tenth, the retainer 203 is advanced longitudinally over the packing sleeve 2150 and dynamic section 202 until the rear shoulder 258 of the dynamic flange section 251 of the retainer 203 abuts the rear surface 2155 of the packing sleeve 2150, as shown in
Eleventh, the retainer 203 is rotated about its longitudinal axis until the radial walls 255 of the retainer 203 align radially with the radial walls 2137 and 2165 of the dynamic section 202 and packing sleeve 2150. This is done in the same manner as described for the similar retainer 103 of fluid end 100 shown in
Twelfth, a retainer lock 205 is oriented and positioned such that the front surface 2139 faces and nearly abuts the rear surface 244 of the rear static section 214. This is done in the same manner as described for the similar retainer lock 105 of fluid end 100 shown in
Thirteenth, the retainer lock 205 is positioned such that the intermediate inner surface 2141 abuts the retainer flange relief section 278 of the dynamic section 202, and the radial walls 2137 are radially aligned with the already aligned radial walls 255 and 2165 of cutout 254 of the retainer 203 and cutout 2164 of the packing sleeve 2150. This is done in the same manner as described for the similar retainer lock 105 of fluid end 100 shown in
Fourteenth, the retainer lock 205 is inserted into the annular space between the dynamic flange section 251 of the through bore 249 of the retainer 203 and the cutout surfaces 2138 and 2166 of the dynamic section 202 and packing sleeve 2150 until the limit shoulder 2145 of the retainer lock 205 abuts the cutout surface 256 of the retainer 203, as shown in
Fifteenth, steps twelve through fourteen are repeated for a second retainer lock 205.
Sixteenth, the plurality of packing stacks 206, plurality of plunger assemblies 207, plurality of packing nuts 208, plurality of packing nut seals 209, plurality of top plunger suction fittings 210, plurality of bottom plunger suction fittings 211, and plurality of suction fitting connectors 212 may be assembled as shown in
Seventeenth, the assembly of the remaining components such as the discharge plug seal 218, discharge valve assembly 217, and discharge plug retainer 219 are assembled as shown in
Assembly steps five through seventeen may be repeated for each flow bore 225 of front static section 213, preferably in the same manner. The assembly of the fluid end 200 is now complete and may be mounted to a power end using stay rods similar to those shown in the '710 patent. After mounting to a power end, suction conduits (not shown) may be attached to the external threads 2110 of the riser sections 2108 of the top plunger fittings 210, and discharge conduits (not shown) may be attached to discharge fittings (not shown) installed in the discharge bore 227.
The advantages in assembly and operation listed for fluid end 100 are all present in fluid end 200. Fluid end 200 has an additional operational advantage—the packing sleeve 2150 eliminates the need for a wear sleeve such as wear sleeve 167 of fluid end 100, thus simplifying maintenance.
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The intermediate outer surface 370 also has areas with different features. Beginning at the front surface 368 and continuing to the rear surface 369, each intermediate outer surface 370 comprises a dynamic seal section 376, an external thread 377, a relief section 378, and a packing sleeve flange 379. The relief section 378 has a smaller diameter than packing sleeve flange 379, thus forming a rear shoulder 380, as shown in
The dynamic section body 365 further comprises a plurality of stud through holes 3168. In this embodiment, there are sixteen stud through holes 3168 to match the number of stud through holes 3169 and 3170 in the packing sleeve 3150 and retainer 303, however there may more or less if desired. Each stud through hole 3168 connects the rear surface 369 and the rear shoulder 380. The bore axis of each stud through hole 3168 is parallel to the longitudinal axis of the dynamic section 302. The stud through holes 3168 are spaced evenly about the circumference of the packing sleeve flange 379. The even circumferential spacing results in an 11.25-degree circumferential spacing between adjacent stud through holes 3168. In alternative embodiments, the circumferential spacing may not be even. The radial location of the stud through holes 3168 is near the intermediate outer surface 370 and far enough from the relief section 378 to allow assembly of the dynamic section connector 3167. The circumferential and radial locations of the stud through holes 3168 match the circumferential and radial locations of the stud through holes 3169 and 3170 in the packing sleeve 3150 and retainer 303 when assembled.
Referring now to
The intermediate outer surface 3156 comprises a packing sleeve seal section 3161 and an outer limit section 3162. The packing sleeve seal section 3161 has a smaller diameter than the outer limit section 3162, thus forming a packing sleeve shoulder 3163, as shown in
The packing sleeve 3150 further comprises a plurality of stud through holes 3169. In this embodiment, there are sixteen stud through holes 3169 to match the number of stud through holes 3168 and 3170 in the dynamic section body 365 and retainer 303, however there may more or less if desired. Each stud through hole 3169 connects the packing sleeve shoulder 3163 and the rear surface 3155. The bore axis of each stud through hole 3169 is parallel to the longitudinal axis of the packing sleeve 3150. The stud through holes 3169 are spaced evenly about the circumference of the packing sleeve shoulder 3163. The even circumferential spacing results in an 11.25-degree circumferential spacing between adjacent stud through holes 3169. In alternative embodiments, the circumferential spacing may not be even. The radial location of the stud through holes 3169 is near the intermediate outer surface 3156. The circumferential and radial locations of the stud through holes 3169 match the circumferential and radial locations of the stud through holes 3168 and 3170 in the dynamic section body 365 and retainer 303 when assembled.
The packing sleeve 3150 further comprises a lubrication port 362 connecting the intermediate outer surface 3156 to the packing section 3159 of the through bore 3157. The lubrication port 362 may have internal threads 363 and/or a counterbore 364 configured to accept a lubrication fitting (not shown) as needed.
Referring now to
The retainer 303 further comprises a plurality of stud through holes 3170. In this embodiment, there are sixteen stud through holes 3170 to match the number of stud through holes 3168 and 3169 in the dynamic section body 365 and packing sleeve 3150, however there may more or less if desired. Each stud through hole 3170 connects the front 346 and rear surfaces 347. The bore axis of each stud through hole 3170 is parallel to the longitudinal axis of the retainer 303. The stud through holes 3170 are spaced evenly about the circumference of the retainer 303. The even circumferential spacing results in an 11.25-degree circumferential spacing between adjacent stud through holes 3170. In alternative embodiments, the circumferential spacing may not be even. The radial location of the stud through holes 3170 is near the intermediate outer surface 348. The circumferential and radial locations of the stud through holes 3170 match the circumferential and radial locations of the stud through holes 3168 and 3169 in the dynamic section body 365 and packing sleeve 3150 when assembled.
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First, the dynamic seals 315 are installed in the static section body 3171 of the static section 301 as shown in
Second, the dynamic sections 302 are assembled by pressing the discharge valve seats 366 into the discharge valve seat sections 372 of the through bores 371 of each dynamic section body 365 and installing the packing sleeve seals 3151 in the packing sleeve seal grooves 3153 of the packing sleeve sections 3152 of the through bores 371, as shown in
Third, each dynamic section 302 is threaded into the static section body 3171, as shown in
Fourth, the packing sleeve seal section 3161 of the intermediate outer surface 3156 of a packing sleeve 3150 is aligned with the through bore 371 of a dynamic section body 365 and inserted into the packing sleeve section 3152 until the packing sleeve shoulder 3163 abuts the rear surface 369 of the dynamic section body 365 as shown in
Fifth, the packing sleeve 3150 is rotated until the stud through holes 3169 align with the stud through holes 3168 of the dynamic section body 365, as shown in
Sixth, the first threaded end 3181 of a stud 3179 is inserted in a stud through hole 3169 of the packing sleeve 3150 and further through an aligned stud through hole 3168 of the dynamic section body 365 until the first threaded end 3181 protrudes from the rear shoulder 380 of the dynamic section body 365, as shown in
Seventh, a nut 3180 is threaded on the protruding first threaded end 3181 as shown in
Eighth, steps six and seven are repeated for each stud through hole 3169. At this point in the assembly, the second threaded ends 3182 will be protruding from the rear surface 3155 of the packing sleeve 3150.
Ninth, the front surface 346 of the retainer 303 is oriented to face the rear surface 3155 of the packing sleeve 3150, as shown in
Tenth, the retainer 303 is advanced longitudinally until the front surface 346 of the retainer 303 abuts the rear surface 3155 of the packing sleeve 3150, as shown in
Eleventh, nuts 3180 are threaded on the second threaded ends 3182 of each of the studs 3179 that are now protruding from the rear surface 347 of the retainer 303, and torqued to specification, as shown in
Twelfth, the packing stack 306 is inserted into the now aligned through bores 349, 3157, and 371 of the retainer 303, packing sleeve 3150, and dynamic section 302, as shown in
Thirteenth, the plunger assembly 307 is inserted in the through bores 349, 3157, and 371 into the packing stack 306, as shown in
Fourteenth, the packing nut seal 309 is inserted into the packing nut 308, as shown in
Fifteenth, the packing nut 308 and installed packing nut seal 309 are threaded into the internal thread 360 of the through bore 349 of the retainer 303, while simultaneously advancing over the plunger assembly 307, and torqued until the desired compressive load is achieved on the packing stack 306, as shown in
Sixteenth, top 310 and bottom 311 plunger suction fittings are assembled to the plunger 3119 using the plurality of suction fitting connectors 312, as shown in
Seventeenth, the discharge valve assembly 317 is assembled as shown in
Eighteenth, the discharge plug seal 318, discharge valve assembly 317, and discharge plug retainer 319 are assembled as shown in
Assembly steps four through eighteen may be repeated for each flow bore 3175 of static section body 3171, preferably in the same manner. The assembly of the fluid end 300 is now complete and it may be mounted to a power end using stay rods similar to those shown in the '710 patent. After mounting to a power end, suction conduits (not shown) may be attached to the external threads 3110 of the riser sections 3108 of the top plunger fittings 310, and discharge conduits (not shown) may be attached to discharge fittings (not shown) installed in the discharge bore 327.
In operation, stress concentrations due to the presence of intersecting bores have been eliminated along with the intersecting bores. This increases the life of the fluid end 300. The fluid end 300 also has the operational advantage of the packing sleeve 3150, which eliminates the need for a wear sleeve such as wear sleeve 167 of fluid end 100, thus simplifying maintenance.
The fluid end described herein has various embodiments of sections, bodies, assemblies, and components attached to each other. One of skill in the art will appreciate that the various sections, bodies, assemblies, and components described herein may have different shapes and sizes, depending on the shape and size of the various sections, bodies, assemblies, and components chosen to assemble each fluid end.
One or more kits may be useful in assembling a fluid end out of the various sections, bodies, assemblies, and components described herein. A single kit may comprise a plurality of one of the various embodiments of sections, bodies, assemblies, and components described herein. The kit may even further comprise a plurality of one or more of the various sections, bodies, assemblies, and components attached to the various sections, bodies, assemblies, and components described herein.
The various features and alternative details of construction of the apparatuses described herein for the practice of the present technology will readily occur to the skilled artisan in view of the foregoing discussion. It is to be understood that even though numerous characteristics and advantages of various embodiments of the present technology have been set forth in the foregoing description, together with details of the structure and function of various embodiments of the technology, this detailed description is illustrative only. Changes may be made in detail, especially in matters of structure and arrangements of parts within the principles of the present technology to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. Changes may also be made in the construction, operation and arrangement of the various parts, elements, steps, and procedures described herein without departing from the spirit and scope of the invention.
| Number | Date | Country | |
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| 62842009 | May 2019 | US | |
| 62872664 | Jul 2019 | US | |
| 62878146 | Jul 2019 | US | |
| 62880409 | Jul 2019 | US | |
| 62882328 | Aug 2019 | US | |
| 62901445 | Sep 2019 | US | |
| 62939339 | Nov 2019 | US | |
| 62950746 | Dec 2019 | US | |
| 63565378 | Mar 2024 | US | |
| 63569201 | Mar 2024 | US | |
| 63571174 | Mar 2024 | US | |
| 63574498 | Apr 2024 | US |
| Number | Date | Country | |
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| Parent | 16860146 | Apr 2020 | US |
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| Number | Date | Country | |
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| Parent | 17987960 | Nov 2022 | US |
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| Parent | 17692420 | Mar 2022 | US |
| Child | 17987960 | US |
| Number | Date | Country | |
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| Parent | 18504546 | Nov 2023 | US |
| Child | 19078772 | US |
