CN210770133U - Five-cylinder plunger pump with integral power end structure - Google Patents
Five-cylinder plunger pump with integral power end structure Download PDFInfo
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- CN210770133U CN210770133U CN201921833173.6U CN201921833173U CN210770133U CN 210770133 U CN210770133 U CN 210770133U CN 201921833173 U CN201921833173 U CN 201921833173U CN 210770133 U CN210770133 U CN 210770133U
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Abstract
The utility model discloses a five jar plunger pumps of integral power end structure adopts whole welded structure to crankcase and cross head box in the five jar plunger pump power end assemblies for the structural strength of power end assembly is higher, and support stability is better, the reducible whole pump vibration. The cylinder spacing is 13-14 inches, the bearing area of the connecting rod, the cross head and the bearing bush is increased, the high-power output of the five-cylinder plunger pump is guaranteed, the problem that the area of a shale gas fracturing well site is small and the number of required fracturing equipment is large can be effectively solved by the high-power five-cylinder plunger pump, the use of the equipment can be reduced, and the well site arrangement is facilitated. The 11-inch long stroke design can better meet the operation requirement of large displacement and improve the operation efficiency. The multipoint support design of the crankshaft box body, the crosshead box body and the hydraulic end assembly can improve the support strength of the five-cylinder plunger pump, reduce vibration, better guarantee high-load operation and more stable operation.
Description
Technical Field
The utility model relates to a plunger pump technical field, concretely relates to five jar plunger pumps of integral power end structure.
Background
Along with the further development of unconventional oil gas and shale oil gas, the requirement of fracturing operation on pressure and discharge capacity is constantly improved, not only is the operating pressure constantly increased along with the increase of horizontal well depth, but also the discharge capacity that single-section well required is higher and higher, and this makes the fracturing construction scale bigger and bigger, and abominable operating mode also provides higher requirement to fracturing equipment especially to the plunger pump. At present, in the shale oil and gas development process, the working pressure generally reaches 80-90MPa or even higher, and the single-stage working displacement is also generally 1800m3-2000m3Even above, the plunger pump not only needs to be capable of meeting continuous operation of high pressure and large discharge capacity, but also needs to ensure quality stability under continuous high-load operation, and pump stopping time and maintenance time are reduced. The most widely applied fracturing truck in the market at present is a 2500-type fracturing truck which is provided with a 2800hp plunger pump, other commonly used fracturing pumps are a 2500hp pump, a 3300hp pump, a 4000hp pump and the like,for example, a 2800hp pump is adopted, because of power limitation, the single pump displacement is low in high-pressure operation, and the displacement requirement of a single section is 14-16m3In addition, the conventional plunger pump is in high-load operation for a long time under the condition of facing increasingly severe operation working conditions, the frequency of problems is increased, and the maintenance and overhaul costs are increased. In recent years, the electric drive fracturing operation is started, the problem of power limitation of a diesel engine is solved by adopting the motor drive, and the electric drive fracturing pump is more suitable for driving a high-power plunger pump.
Along with the improvement of the power of the plunger pump, higher requirements are also put forward on the running stability of the plunger pump, and especially the requirements on the strength, the supporting stability and the like of a power end structure of the plunger pump are higher.
SUMMERY OF THE UTILITY MODEL
The utility model discloses an it is not enough that prior art is overcome to the purpose, provides a five jar plunger pumps of integral power end structure, adopts whole welded structure to crankcase and cross head box in the five jar plunger pump power end assemblies for the structural strength of power end assembly is higher, and support stability is better, the reducible whole pump vibration. The cylinder spacing is 13-14 inches, the high-power output of the five-cylinder plunger pump is guaranteed, the specific power of the five-cylinder plunger pump can reach 7000hp, the problem that the area of a shale gas fracturing well site is small and the number of required fracturing equipment is large can be effectively solved by the high-power five-cylinder plunger pump, the use of the equipment can be reduced, and the well site arrangement is facilitated. The 11-inch long stroke design can better meet the operation requirement of large displacement and improve the operation efficiency. The multipoint support design of the crankshaft box body, the crosshead box body and the hydraulic end assembly can improve the support strength of the five-cylinder plunger pump, reduce vibration, better guarantee high-load operation and more stable operation. The five-cylinder plunger pump adopts two-stage speed reduction of a planetary reduction gearbox and a parallel reduction gearbox, which is beneficial to obtaining a large speed reduction ratio, the input torque can be reduced by increasing the speed reduction ratio, the service life of the reduction gearbox is prolonged, and the model selection of an engine and a motor is better matched; the reduction ratio is increased, the stroke frequency of the five-cylinder plunger pump can be effectively reduced, and the service life of each part is prolonged.
The utility model discloses a realize through following technical scheme: a five-cylinder plunger pump with an integral power end structure comprises a power end assembly, a hydraulic end assembly and a reduction gearbox assembly, wherein one end of the power end assembly is connected with the hydraulic end assembly, the other end of the power end assembly is connected with the reduction gearbox assembly, the power end assembly comprises a crankcase body, a crosshead case body and a spacing frame, the crankcase body and the crosshead case body are integrally welded to form a power end shell, the power end shell is connected with the spacing frame, the power end shell comprises vertical plates, bearing seats, front end plates, a rear cover plate, a bottom plate, a supporting plate and an upper cover plate, the number of the vertical plates is 6, the number of the bearing seats is 6, one vertical plate is correspondingly connected with one bearing seat, the 6 vertical plates are arranged in parallel to form a power end cavity, the bottom plate is arranged at the bottom of the power end cavity, and the upper cover plate is arranged at the top of the power end, the front end of the power end cavity is provided with a front end plate, the rear end of the power end cavity is provided with a rear cover plate, and a support plate is arranged between two adjacent vertical plates which are arranged in parallel.
Furthermore, a crankshaft support body is arranged at the bottom of the crankcase body and used for supporting the crankcase body.
Furthermore, a crosshead support body is arranged at the bottom of the crosshead box body and is used for supporting the crosshead box body.
Furthermore, a hydraulic support body is arranged at the bottom of the spacing frame and used for supporting the hydraulic end assembly.
Furthermore, a crankshaft is arranged in the crankcase body and is integrally forged by alloy steel, the crankshaft comprises six shaft necks and five crank throws, one crank throw is arranged between every two adjacent shaft necks, and the cylinder spacing of the five-cylinder plunger pump is 13-14 inches.
Furthermore, a spline is arranged in the crankshaft, and the reduction gearbox assembly is connected with the spline of the crankshaft.
Furthermore, a crosshead assembly is arranged in the crosshead box body, a connecting rod assembly is arranged between the crankcase body and the crosshead box body, a crankshaft is arranged in the crankcase body, one end of the connecting rod assembly is connected with the crankshaft through a connecting rod bearing bush, the other end of the connecting rod assembly is connected with the crosshead assembly through a crosshead bearing bush, and the connecting rod bearing bush and the crosshead bearing bush are steel back bearing bushes with alloy coatings.
Further, the stroke of the five-cylinder plunger pump of the integrated power end structure is 11 inches.
Furthermore, the reduction gearbox assembly comprises a planetary reduction gearbox and a parallel reduction gearbox, one end of the planetary reduction gearbox is connected with the power end assembly, the other end of the planetary reduction gearbox is connected with the parallel reduction gearbox, secondary reduction of the reduction gearbox assembly is achieved through the planetary reduction gearbox and the parallel reduction gearbox, and the reduction ratio is 8:1-15: 1.
Compared with the prior art, the beneficial effects of the utility model are that: 1. the crankshaft box body and the crosshead box body in the power end assembly of the five-cylinder plunger pump are in an integral welding structure, so that the structural strength of the power end assembly is higher, the supporting stability is better, and the vibration of the whole pump can be reduced. 2. The cylinder spacing is 13-14 inches, the bearing area of connecting rods, the crosshead and bearing bushes is increased, guarantee is provided for high-power output of the five-cylinder plunger pump, the power of the specific five-cylinder plunger pump can reach 7000hp, the problem that shale gas fracturing well site area is small and the number of required fracturing equipment is large can be effectively solved by the high-power five-cylinder plunger pump, the use of equipment can be reduced, and well site arrangement is facilitated. 3. The 11-inch long stroke design can better meet the operation requirement of large displacement and improve the operation efficiency. 4. The multipoint support design of the crankshaft box body, the crosshead box body and the hydraulic end assembly can improve the support strength of the five-cylinder plunger pump, reduce vibration, better guarantee high-load operation and more stable operation. 5. The five-cylinder plunger pump adopts two-stage speed reduction of a planetary reduction gearbox and a parallel reduction gearbox, which is beneficial to obtaining a large speed reduction ratio, the input torque can be reduced by increasing the speed reduction ratio, the service life of the reduction gearbox is prolonged, and the model selection of an engine and a motor is better matched; the reduction ratio is increased, the stroke frequency of the five-cylinder plunger pump can be effectively reduced, and the service life of each part is prolonged.
The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.
Drawings
Fig. 1 is a schematic structural view of a five-cylinder plunger pump.
FIG. 2 is a schematic diagram of a power end assembly.
FIG. 3 is a schematic diagram of the power end housing construction.
Fig. 4 is a schematic structural view of the reduction gearbox assembly.
Fig. 5 is a cross-sectional view of a planetary stage reduction gearbox.
Fig. 6 is a cross-sectional view of a parallel stage reduction gearbox.
Fig. 7 is a schematic structural view of the crankshaft.
FIG. 8 is a schematic view of the connection of the link assembly to the crosshead assembly.
Wherein, 1, a power end assembly, 2, a reduction gearbox assembly, 3, a hydraulic end assembly, 4, a driving flange, 5, a power end shell, 6, a crankshaft, 7, a bearing, 8, a connecting rod bearing bush, 9, a connecting rod body, 10, a slide rail, 11, a crosshead, 12, a crosshead bearing bush, 13, a pull rod, 14, a spacing frame, 15, a long screw rod, 16, a nut, 17, a hoop, 18, a plunger, 19, a valve box, 20, a crankshaft support body, 21, a crosshead support body, 22, a hydraulic support body, 23, a rear cover plate, 24, a vertical plate, 25, a bearing seat, 26, a bottom plate, 27, a support plate, 28, a front end plate, 29, an upper cover plate, 30, a parallel stage reduction gearbox, 31, a planet stage reduction gearbox, 32, an inner gear ring, 33, a planet wheel, 34, a sun wheel, 35, a planet carrier, 36, a large gear, 37, a small gear, 38, a spline, 41. crosshead gland, 42, guide plate, 43, screw.
Detailed Description
In the embodiment, as shown in fig. 1 to 8, a five-cylinder plunger pump with an integral power end structure comprises a power end assembly 1, a hydraulic end assembly 3 and a reduction gearbox assembly 2, wherein one end of the power end assembly 1 is connected with the hydraulic end assembly 3, the other end of the power end assembly 1 is connected with the reduction gearbox assembly 2, the power end assembly 1 comprises a crankcase body, a crosshead body and a spacer 14, the crankcase body and the crosshead body are integrally welded to form a power end housing 5, the power end housing 5 is connected with the spacer 14, the power end housing 5 comprises vertical plates 24, bearing seats 25, a front end plate 28, a rear cover plate 23, a bottom plate 26, a support plate 27 and an upper cover plate 29, the number of the vertical plates 24 is 6, the number of the bearing seats 25 is 6, one vertical plate 24 is correspondingly connected with one bearing seat 25, and the 6 vertical plates 24 are arranged in parallel to form a power end cavity, a bottom plate 26 is arranged at the bottom of the power end cavity, an upper cover plate 29 is arranged at the top of the power end cavity, a front end plate 28 is arranged at the front end of the power end cavity, a rear cover plate 23 is arranged at the rear end of the power end cavity, and a support plate 27 is arranged between two adjacent vertical plates 24 which are arranged in parallel. The crankshaft box body and the crosshead box body in the power end assembly 1 of the five-cylinder plunger pump are in an integral welding structure, so that the structural strength of the power end assembly 1 is higher, the supporting stability is better, the bearing deformation of the power end shell 5 can be effectively reduced, the vibration of the whole pump can be reduced, and the running stability of the five-cylinder plunger pump is improved.
The bottom of the crankcase body is provided with a crankshaft support body 20, and the crankshaft support body 20 is used for supporting the crankcase body. The bottom of the crosshead box body is provided with a crosshead support body 21, and the crosshead support body 21 is used for supporting the crosshead box body. The bottom of the spacing frame 14 is provided with a hydraulic support body 22, and the hydraulic support body 22 is used for supporting the hydraulic end assembly 3. The five-cylinder plunger pump adopts a multipoint support design, so that the support strength of the five-cylinder plunger pump can be improved, the vibration is reduced, the high-load operation is better ensured, and the operation is more stable.
The crankshaft 6 and the bearing 7 are arranged in the crankcase body, the crankshaft 6 is integrally forged by alloy steel, the crankshaft 6 comprises six shaft necks and five crank throws, one crank throw is arranged between every two adjacent shaft necks, and the cylinder spacing of the five-cylinder plunger pump is 13-14 inches. The design of increasing the cylinder interval is favorable to increasing the area of contact of bent axle 6 and connecting rod axle bush 8, cross head 11 and slide rail 10, improves support strength. The high-power output of the five-cylinder plunger pump is guaranteed, the problem that the shale gas fracturing well site is small in area and many required fracturing equipment are effectively solved by the high-power five-cylinder plunger pump, the use of the equipment can be reduced, and the well site arrangement is facilitated. The number of the bearings 7 is 6, 6 bearings 7 are arranged on six shaft necks, and the outer rings of the bearings 7 are assembled on 6 bearing seats 25 of the power end shell 5, so that the rotary motion can be realized in the bearing seats 25.
The crankshaft 6 is internally provided with a spline 38, the reduction gearbox assembly 2 is connected with the power end shell 5 through a bolt, the reduction gearbox assembly 2 is provided with an external spline, the external spline is connected with the spline 38 and used for power output, and the installation angle of the reduction gearbox assembly 2 can be adjusted according to input requirements. A driving flange 4 is arranged outside the reduction gearbox assembly 2, and a power source is externally connected through the driving flange 4 to realize power input.
The crosshead assembly is arranged in the crosshead box body, the connecting rod assembly is arranged between the crankcase body and the crosshead box body, the crankshaft 6 is arranged in the crankcase body, one end of the connecting rod assembly is connected with the crankshaft 6 through the connecting rod bearing bush 8, the other end of the connecting rod assembly is connected with the crosshead assembly through the crosshead bearing bush 12, reciprocating swing can be achieved, and the other end of the crosshead assembly is connected with the pull rod 13. The pull rod 13 is of a hollow structure. The connecting rod bearing bush 8 and the crosshead bearing bush 12 are both steel-backed bearing bushes with alloy coatings. The width-diameter ratio is large, and the supporting strength is high.
The power end shell 5 is internally provided with a supporting plate 27 on which 2 sliding rails 10 are fixed, wherein the 2 sliding rails 10 form a semicircular space, and the crosshead 11 is arranged in the semicircular space and can realize reciprocating linear motion.
The crosshead assembly is designed in a split structure and comprises a crosshead gland 41 and a crosshead 11, and the crosshead gland 41 is connected with the crosshead 11 so as to be convenient for assembling and disassembling with the connecting rod assembly.
The connecting rod assembly comprises a connecting rod cover 39 and a connecting rod body 9, the connecting rod cover 39 and the connecting rod body 9 are formed by cutting after integral forging, the strength is high, the connecting rod cover 39 and the connecting rod body 9 are connected through bolts, specifically, one end of the connecting rod body 9 is connected with a crank through the connecting rod cover 39, a connecting rod bolt 40 and a connecting rod bearing bush 8, and the other end of the connecting rod body 9 is connected with a crosshead 11 through a crosshead gland 41 and a crosshead bearing bush 12. Guide plates 42 are fixed to the upper and lower ends of the crosshead 11 by screws 43, and the guide plates 42 are made of a copper alloy material and directly contact the slide rail 10 to move relative to each other.
And lubricating oil paths are designed on the crankshaft 6, the connecting rod body 9 and the crosshead 11 and are used for lubricating the bearing 7, the connecting rod bearing bush 8 and the crosshead bearing bush 12.
The hydraulic end assembly 3 comprises a valve box 19, a plunger 18, a clamp 17 and the like, the plunger 18 and the pull rod 13 are connected together through the clamp 17 and are fixed on the spacing frame 14 through a long screw 15 and a nut 16, and the long screw 15 is connected to the power end shell 5 through threads.
The stroke of the five-cylinder plunger pump of the integrated power end structure is 11 inches. The long-stroke design is very suitable for the current shale gas fracturing zipper type operation requirement, the number of well site equipment is reduced, and the operation efficiency and the economical efficiency are improved.
The reduction gearbox assembly 2 comprises a planetary reduction gearbox 31 and a parallel reduction gearbox 30, one end of the planetary reduction gearbox 31 is connected with the power end assembly 1, the other end of the planetary reduction gearbox 31 is connected with the parallel reduction gearbox 30, secondary speed reduction of the reduction gearbox assembly 2 is achieved through the planetary reduction gearbox 31 and the parallel reduction gearbox 30, and the reduction ratio is 8:1-15: 1. The parallel reduction gearbox 30 comprises a bull gear 36 and a pinion gear 37 and performs primary reduction; the planetary reduction gearbox 31 is a planetary gear mechanism consisting of an annular gear 32, four planetary gears 33, a sun gear 34 and a planet carrier 35 and performs secondary reduction. The sun gear 34 is located in the center of the planetary gear mechanism, meshes with the planet gears 33, and is coaxial with the large gear 36 of the parallel stage reduction gearbox 30. When the driving device operates, the external power source of the driving flange 4 drives the input shaft to rotate, the input shaft is transmitted to the large gear 36 through the small gear 37 to realize primary speed reduction, the input shaft is transmitted to the sun gear 34 through the large gear 36, the sun gear 34 drives the planet carrier 35 through the planet gear 33 to realize secondary speed reduction, and finally power is transmitted to the crankshaft 6 through the spline 38. The large transmission ratio can be obtained through two-stage speed change, the input torque is effectively reduced, and the stroke frequency of the pump is reduced.
The working principle is as follows: external power or rotating speed drive the reduction box assembly 2 to rotate through the driving flange 4, power and torque are transmitted to the crankshaft 6 through the spline 38 through two-stage speed change, the crankshaft 6 and the bearing 7 rotate in the power end shell 5 to drive the connecting rod body 9, the crosshead 11 and the pull rod 13 to move, the rotating motion of the crankshaft 6 is converted into reciprocating linear motion of the pull rod 13, and the pull rod 13 drives the plunger 18 to reciprocate in the valve box 19 through the hoop 17, so that suction of low-pressure liquid and discharge of high-pressure liquid are realized, and pumping of the liquid is realized.
It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.
Claims (9)
1. The utility model provides a five jar plunger pumps of integral power end structure, includes power end assembly, fluid end assembly and reducing gear box assembly, the one end and the fluid end assembly of power end assembly are connected, the power end assembly other end is connected with the reducing gear box assembly, its characterized in that: the power end assembly comprises a crankshaft box body, a crosshead box body and a spacing frame, wherein the crankshaft box body and the crosshead box body are integrally welded to form a power end shell, the power end shell is connected with the spacing frame, the power end shell comprises vertical plates, bearing seats, a front end plate, a rear cover plate, a bottom plate, a supporting plate and an upper cover plate, the number of the vertical plates is 6, the number of the bearing seats is 6, one vertical plate is correspondingly connected with one bearing seat, the 6 vertical plates are arranged in parallel to form a power end cavity, the bottom of the power end cavity is provided with the bottom plate, the top of the power end cavity is provided with the upper cover plate, the front end plate is arranged at the front end of the power end cavity, the rear end plate is arranged at the rear end of the power end cavity, and the supporting plate is arranged between every two.
2. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the bottom of the crankcase body is provided with a crankshaft support body, and the crankshaft support body is used for supporting the crankcase body.
3. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the crosshead support body is arranged at the bottom of the crosshead box body and is used for supporting the crosshead box body.
4. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: and a hydraulic support body is arranged at the bottom of the spacing frame and is used for supporting the hydraulic end assembly.
5. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the crankshaft is arranged in the crankshaft box body and is integrally forged by alloy steel, the crankshaft comprises six shaft necks and five crank throws, one crank throw is arranged between every two adjacent shaft necks, and the cylinder spacing of the five-cylinder plunger pump is 13-14 inches.
6. The five-cylinder plunger pump of unitary power end structure of claim 5, wherein: a spline is arranged in the crankshaft, and the reduction gearbox assembly is connected with the crankshaft spline.
7. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the crosshead assembly is arranged in the crosshead box body, the connecting rod assembly is arranged between the crankshaft box body and the crosshead box body, the crankshaft is arranged in the crankshaft box body, one end of the connecting rod assembly is connected with the crankshaft through a connecting rod bearing bush, the other end of the connecting rod assembly is connected with the crosshead assembly through a crosshead bearing bush, and the connecting rod bearing bush and the crosshead bearing bush are steel-backed bearing bushes with alloy coatings.
8. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the stroke of the five-cylinder plunger pump of the integrated power end structure is 11 inches.
9. The five-cylinder plunger pump of unitary power end structure of claim 1, wherein: the reduction gearbox assembly comprises a planetary reduction gearbox and a parallel reduction gearbox, one end of the planetary reduction gearbox is connected with the power end assembly, the other end of the planetary reduction gearbox is connected with the parallel reduction gearbox, secondary reduction of the reduction gearbox assembly is achieved through the planetary reduction gearbox and the parallel reduction gearbox, and the reduction ratio is 8:1-15: 1.
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