CN212898899U - Submersible single-cylinder plunger oil pump - Google Patents

Submersible single-cylinder plunger oil pump Download PDF

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Publication number
CN212898899U
CN212898899U CN202021133095.1U CN202021133095U CN212898899U CN 212898899 U CN212898899 U CN 212898899U CN 202021133095 U CN202021133095 U CN 202021133095U CN 212898899 U CN212898899 U CN 212898899U
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cam
lubricating oil
inclined plane
inclined surface
plunger
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陈明海
陈英峰
刘和平
柯西
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Ningbo Heli Machine Pump Co ltd
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Ningbo Heli Machine Pump Co ltd
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Abstract

The utility model relates to a dive well formula single cylinder plunger oil-well pump, including hydraulic end, power end, latent oily motor and lubricating oil supply unit, above-mentioned each part top-down connects gradually the combination and forms wholly roughly the cylinder structure, and the lower extreme of the sliding sleeve of power end is connected with the cam subassembly and is formed an organic whole piece, and the cover is established in the outside of camshaft together, and can convert camshaft rotary motion into the up-and-down reciprocating motion of sliding sleeve; the bottom of a lubricating oil storage tank of the lubricating oil supply unit is connected with the top of the pump body to form an integral structure, the lower end of the medium conveying pipe penetrates out of the lubricating oil storage tank and is communicated with a liquid outlet of the pump body, the upper end of the medium conveying pipe penetrates out of the lubricating oil storage tank to form a liquid outlet pipe opening, and an oil storage cavity of the lubricating oil storage tank is communicated with a lubricating oil flow passage of the pump body. The utility model discloses reduced the well lifting maintenance frequency, reduced manufacturing cost, and made oil-well pump overall structure arrange more rationally, reduced the volume, can satisfy better and use in vertical well, inclined shaft, low-yield well.

Description

Submersible single-cylinder plunger oil pump
Technical Field
The utility model relates to an oil-well pump technical field especially relates to a dive well formula single cylinder plunger oil-well pump.
Background
Oil wells in oil fields at home and abroad are mostly ground pumping units, and part of wells are also provided with screw pumps, centrifugal pumps, hydraulic piston pumps and the like. Generally, a power source is arranged on the ground, a pump is arranged underground, various oil pumping devices have low efficiency, the device and power are large, and the service life of a wearing part is short.
Because the oil well is hundreds of meters or even kilometers deep, the cost of oil pump maintenance and well lifting is very high, and tens of thousands or tens of thousands of yuan is needed at one time, so that the use cost is high. The oil pumping equipment is also one of the reasons for large power consumption and high cost of the oil field. At present, the most widely applied oil pumping unit (head knocking machine) at home and abroad is the most traditional oil pumping unit, the market demand of the oil well pump is the greatest, but the oil well pump is not suitable for pumping oil from a low-yield well, the oil pumping rod is easy to lose, the annual consumption number of the oil pumping rod in domestic oil fields is thousands of tons, and the number of the loss cost is huge. Under the large environment, the oil field is environment-friendly and innovative, is the number of working ports of vast oil workers, the great revolution of oil pumping equipment is already developed, the oil field is eagerly to replace the traditional oil pumping equipment, the call is great, and a low-yield well waits for the emergence of a new generation of oil pumping equipment. In addition, because the pump must potentially operate in an oil medium due to the size limitations of the internal cavity of the oil well tubing string, the outer diameter of the pump is a challenge, the smaller the better.
In order to solve the technical problems, the Chinese patent with the application number of CN201810323601.4 (with the publication number of CN108302021A) discloses a submersible single-cylinder vertical plunger oil well pump, which comprises a hydraulic end, a power end and a submersible motor, wherein the hydraulic end comprises a pump body which is a cylindrical shell, the top of the pump body is externally connected with a liquid discharge pipeline, and the bottom of the pump body is connected with a cylindrical machine body of the power end; the combination valve and the plunger are respectively arranged in the pump body from top to bottom, wherein the combination valve adopts an integrated structure that a liquid discharge valve is arranged above and a liquid inlet valve is arranged below; the power end comprises the cylindrical machine body, and the top and the bottom of the machine body are respectively connected with the pump body and the submersible motor, so that the whole pump forms a circular tubular structure; the lower end of the camshaft is connected with a submersible motor shaft, and the upper part of the camshaft is provided with at least one inclined cam; the lifting shaft can be positioned in the machine body in a vertically sliding manner, is provided with an axial inner hole which penetrates through the lifting shaft up and down, and is provided with a plunger rod connected with a plunger piston at the power end at the upper part of the inner hole to form a reciprocating motion link; the upper part of the camshaft is positioned at the lower part of the inner hole of the lifting shaft, at least one inner inclined surface buckle meshed with the inclined surface cam molded line on the camshaft is arranged in the inner hole of the lifting shaft, and the rotary motion of the camshaft is converted into the up-and-down reciprocating motion of the lifting shaft after the lifting shaft is matched with the molded line of the camshaft through the inner inclined surface buckle. This patent is integrated as an organic whole with hydraulic end, power end, oily motor of diving, realizes rotatory and function integration that reciprocates, has improved greatly and has pumped oil efficiently, and can effectively reduce the energy consumption, and dismouting simple process, convenience, longe-lived, be particularly suitable for the low-yield well and pump the operating mode.
However, the submersible single-cylinder vertical plunger oil pump in the above patent has certain disadvantages, firstly, because the difficulty of configuring the lubricating oil storage tank and the corresponding oil supply component on the oil pump is high, the oil pump is not provided with a corresponding lubricating oil supply unit, so that the plunger and the plunger packing group cannot be effectively lubricated, the damage of the oil pump is easily caused, the maintenance frequency is high, and the cost for one-time up and down lifting of the oil pump is very high. Secondly, the inclined plane cam of the camshaft of the power end of the oil well pump is arranged in the same inclined direction, correspondingly, when each inclined plane cam of the camshaft is matched with the corresponding inclined plane buckle of the inner hole of the lifting shaft in a driving mode, the inclined plane cams act on the same side of the lifting shaft, the accommodating mode leads the lifting shaft to have large advancing resistance due to certain radial force during reciprocating motion, parts are prone to being worn quickly in serious situations, and therefore the oil well pump needs to be frequently lifted out of a well and then maintained and replaced. In view of this, how to design a submersible single-cylinder plunger oil pump which can be integrally lowered to various wells for oil pumping operation and has high reliability and low failure rate has become a technical problem to be solved urgently by those skilled in the art.
SUMMERY OF THE UTILITY MODEL
The utility model aims to solve the technical problem that to prior art's current situation, provide one kind can wholly go down various oil pumping operations in the pit, and the latent well formula single cylinder plunger oil-well pump that the reliability is high, the fault rate is low.
The utility model provides a technical scheme that above-mentioned technical problem adopted does: the submersible single-cylinder plunger oil pump comprises a hydraulic end, a power end, a submersible motor and a lubricating oil supply unit, wherein the lubricating oil supply unit, the hydraulic end, the power end and the submersible motor are sequentially connected from top to bottom to form an overall approximately cylindrical structure;
the power end includes:
the top of the machine body is connected with the pump body at the hydraulic end, and the bottom of the machine body is connected with the submersible motor;
the lower end of the camshaft is connected with an output shaft of the submersible motor;
the transmission mechanism can be constrained in the machine body in a vertically sliding manner and comprises a sliding sleeve and a cam assembly, the upper end of the sliding sleeve is connected with the plunger body at the hydraulic end, the lower end of the sliding sleeve is connected with the cam assembly to form an integral piece, the sliding sleeve and the cam assembly are sleeved on the outer side of the camshaft together, and the rotating motion of the camshaft can be converted into the vertical reciprocating motion of the sliding sleeve;
the fluid end includes:
the pump body is a cylindrical shell, the top of the pump body is provided with a liquid outlet, the bottom of the pump body is connected with the machine body at the power end, and the pump body is also provided with a lubricating oil flow channel;
the combination valve and the plunger body are respectively arranged in the pump body from top to bottom, wherein the combination valve adopts an integrated structure that a liquid discharge valve is arranged above and a liquid inlet valve is arranged below;
the lubricating oil supply unit comprises a lubricating oil storage tank with an oil storage cavity and a medium conveying pipe arranged in the lubricating oil storage tank in a built-in mode, the lubricating oil storage tank is integrally cylindrical, the bottom of the lubricating oil storage tank is connected with the top of the pump body to form an integrated structure, the lower end of the medium conveying pipe penetrates out of the lubricating oil storage tank and is communicated with a liquid discharge port of the pump body, the upper end of the medium conveying pipe penetrates out of the lubricating oil storage tank to form a liquid discharge pipe opening, and the oil storage cavity of the lubricating oil storage tank is communicated.
In order to enable the submersible oil motor to be electrically connected with a control cabinet on the ground, the submersible oil motor further comprises a transfusion hose which is connected to a liquid outlet pipe orifice of the medium conveying pipe and extends to the ground, and the transfusion hose is of a composite pipeline structure filled with cables.
As an improvement, the hydraulic end further includes a plunger packing assembly and a piston cylinder sleeve assembly besides the pump body, the combination valve and the plunger body, the plunger body includes a piston section located at the upper portion and a plunger section located at the lower portion, the plunger packing assembly is arranged at the lower portion of the pump body and correspondingly sleeved outside the plunger section of the plunger body, the piston cylinder sleeve assembly is arranged at the upper portion of the pump body and correspondingly sleeved outside the piston section of the plunger body, the pump body is further provided with an oil pool communicated with the lubricating oil flow passage, and the oil pool is correspondingly located between the piston cylinder sleeve assembly and the plunger packing assembly. The mode that adopts plunger packing to seal and piston cylinder sleeve seal to combine together has realized that the secondary structure is sealed, has further improved the stability of the plunger body reciprocating motion of oil-well pump. On the other hand, lubricating oil in the lubricating oil storage tank can effectively lubricate the plunger packing assembly and the piston cylinder sleeve assembly through the lubricating oil flow channel and the oil pool, so that the friction coefficient is reduced, and the service life of moving parts such as a plunger section, a piston section and the like of the plunger body is prolonged
In order to firmly assemble the plunger packing assembly and the piston cylinder sleeve assembly in the pump body, a first inner step at the lower part and a second inner step at the upper part are also arranged in the pump body, and the plunger packing assembly is pressed on the first inner step through a first pressing nut;
and a conical sleeve is arranged between the bottom of the valve body of the combination valve and the top of the piston cylinder sleeve assembly, a valve pressing sleeve is further arranged on the upper portion of the valve body of the combination valve, and the valve pressing sleeve, the combination valve, the conical sleeve and the piston cylinder sleeve assembly are sequentially pressed on the second inner step under the condition that the bottom of the lubricating oil storage tank is connected to the top of the pump body.
In order to convert the rotational motion of the camshaft into the up-and-down reciprocating motion of the sliding sleeve, the cam assembly comprises:
the main cam piece group comprises a first inclined plane cam and a second inclined plane cam, the first inclined plane cam and the second inclined plane cam are sleeved on the cam shaft and can synchronously rotate along with the cam shaft, and the inclination directions of the first inclined plane cam and the second inclined plane cam are opposite when the first inclined plane cam and the second inclined plane cam are assembled on the cam shaft;
the first auxiliary cams are corresponding to the main cam pieces and are arranged between the first inclined plane cam and the second inclined plane cam of one group of main cam pieces, the upper end surface and the lower end surface of the first auxiliary cam are respectively a first inclined surface and a second inclined surface which are inclined relative to the axis of the first auxiliary cam, wherein the inclination directions of the first inclined plane and the second inclined plane are opposite, the upper end of the first auxiliary cam is fixedly connected with the bottom end of the sliding sleeve, the bottom surface of the sliding sleeve is a third inclined surface which is consistent with the inclined direction of the first inclined surface of the first auxiliary cam, a first movable cavity for accommodating the first inclined cam is reserved between the first inclined surface and the third inclined surface, and point contact connection is carried out between the upper end surface of the first inclined cam and the third inclined surface of the sliding sleeve and between the lower end surface of the first inclined cam and the first inclined surface of the first auxiliary cam;
and the second auxiliary cam is correspondingly arranged below the first auxiliary cam and fixedly connected with the first auxiliary cam, the upper end surface of the second auxiliary cam is a fourth inclined surface consistent with the inclined direction of the second inclined surface of the first auxiliary cam, a second movable cavity for accommodating the second inclined surface cam is reserved between the second inclined surface and the fourth inclined surface, and the upper end surface of the second inclined surface cam and the second inclined surface of the first auxiliary cam and the lower end surface of the second inclined surface cam and the fourth inclined surface of the second auxiliary cam are in point contact connection.
By the aid of the structural design, the components of the power end can be assembled conveniently, and production cost is reduced.
As an improvement, a first spherical concave point is arranged at the lower position of a third inclined plane of the sliding sleeve, a first steel ball is arranged in the first spherical concave point, and the upper end surface of the first inclined plane cam directly or indirectly abuts against the first steel ball, so that point contact connection between the upper end surface of the first inclined plane cam and the third inclined plane of the sliding sleeve is formed;
a second spherical concave point is arranged at the lower position of the second inclined surface of the first auxiliary cam, a second steel ball is arranged in the first spherical concave point, and the upper end surface of the first inclined cam is directly or indirectly abutted against the second steel ball, so that point contact connection between the upper end surface of the second inclined cam and the second inclined surface of the first auxiliary cam is formed;
a third spherical concave point is arranged at the lower position of the first inclined plane of the first auxiliary cam, a third steel ball is arranged in the third spherical concave point, and the lower end face of the first inclined plane cam is abutted against the third steel ball, so that point contact connection between the lower end face of the first inclined plane cam and the first inclined plane of the first auxiliary cam is formed;
a fourth spherical concave point is arranged at the lower position of a fourth inclined plane of the second auxiliary cam, a fourth steel ball is arranged in the fourth spherical concave point, and the lower end face of the second inclined plane cam is abutted against the fourth steel ball, so that point contact connection between the lower end face of the second inclined plane cam and the fourth inclined plane of the second auxiliary cam is formed.
Because the driving force required by the oil well pump in the liquid discharging process is relatively large, in order to avoid the damage of the first inclined cam and the second inclined cam caused by overlarge acting force in the process of driving the plunger body to move upwards, a first annular groove which is coaxial with the first inclined cam is arranged on the upper end surface of the first inclined cam, a first sliding shoe piece which can move relative to the first inclined cam is arranged in the first annular groove, and the first sliding shoe piece is matched on a first steel ball in a first spherical concave point;
the upper end surface of the second inclined cam is provided with a second annular groove which is coaxial with the second inclined cam, a second sliding shoe piece which can move relative to the second inclined cam is arranged in the second annular groove, and the second sliding shoe piece is matched on a second steel ball in a second spherical concave point.
In order to fix the first inclined plane cam and the second inclined plane cam on the cam shaft at intervals and firmly, the cam shaft further comprises an upper pressing sleeve, a middle pressing sleeve and a lower pressing sleeve which are sequentially sleeved on the cam shaft from top to bottom and can synchronously rotate along with the cam shaft, the upper end of the lower pressing sleeve is abutted against the lower end face of the second inclined plane cam, the upper end and the lower end of the middle pressing sleeve are respectively abutted against the lower end face of the first inclined plane cam and the upper end face of the second inclined plane cam, the lower end of the upper pressing sleeve is abutted against the upper end face of the first inclined plane cam, and the upper end of the cam shaft further locks the upper pressing sleeve, the first inclined plane cam, the middle pressing sleeve, the second inclined plane cam and the lower pressing sleeve on the cam shaft downwards through a second pressing nut.
As an improvement, the upper pressing sleeve, the first inclined plane cam, the middle pressing sleeve, the second inclined plane cam and the lower pressing sleeve are connected with the camshaft in a spline mode.
In order to ensure the stability of the camshaft in the rotating process and the sliding sleeve in the up-and-down reciprocating movement process, the lower part of the camshaft is matched with the lower part of the machine body through a first sliding bearing and a thrust ball bearing, the upper part of the camshaft is matched with the inner hole at the lower end of the sliding sleeve through a second sliding bearing, and the upper end part of the sliding sleeve is matched with the upper part of the machine body through a third sliding bearing.
Compared with the prior art, the utility model has the advantages that: the utility model provides an oil-well pump for will diving oily motor, power end, fluid end and lubricating oil storage tank combination and make up into integrative many gang combination single cylinder plunger oil-well pump, wherein, set up lubricating oil supply unit at the oil-well pump top, can make and can obtain effective lubrication between the plunger body and the filler subassembly or the cylinder liner subassembly that correspond, avoid the plunger body to rub futilely and damage, reduced and carried well maintenance frequency, reduced manufacturing cost. On the other hand, the lubricating oil storage tank of the lubricating oil supply unit is directly assembled at the top of the pump body, so that the whole oil well pump is of a roughly cylindrical structure, oil discharged from the hydraulic end of the oil well pump is upwards discharged through a medium conveying pipe arranged in the lubricating oil storage tank, the structural design enables the whole structure of the oil well pump to be more reasonable in arrangement, the size is reduced, and the oil well pump can be better used in a vertical well, an inclined well and a low-yield well.
Drawings
Fig. 1 is a schematic structural diagram of an embodiment of the present invention;
FIG. 2 is a schematic diagram of a hydraulic end portion of an embodiment of the present invention;
FIG. 3 is a schematic structural view of a power end portion of an embodiment of the present invention;
FIG. 4 is a schematic structural diagram of a lubricating oil supply unit according to an embodiment of the present invention;
fig. 5 is a schematic structural diagram of the fuselage according to an embodiment of the present invention;
fig. 6 is a schematic structural view of a camshaft according to an embodiment of the present invention;
fig. 7 is a top view of a camshaft according to an embodiment of the present invention;
fig. 8 is a schematic structural view of the sliding sleeve according to the embodiment of the present invention;
fig. 9 is a cross-sectional view of a first assist cam according to an embodiment of the present invention;
fig. 10 is a cross-sectional view of a second assist cam in accordance with an embodiment of the present invention;
fig. 11 is a top view of a first inclined cam according to an embodiment of the present invention (a second inclined cam has the same structure as the first inclined cam);
FIG. 12 is a cross-sectional view taken at A-A of FIG. 11;
fig. 13 is a top view of an upper press sleeve according to an embodiment of the present invention;
FIG. 14 is a cross-sectional view taken at A-A of FIG. 13;
fig. 15 is a top view of a lower sleeve according to an embodiment of the present invention;
fig. 16 is a cross-sectional view taken at a-a in fig. 15.
Reference numerals: 10. a lubricating oil storage tank; 100. an oil storage chamber; 11. a medium delivery pipe; 110. a liquid outlet pipe orifice; 12. a flexible infusion tube; 21. a pump body; 210. a liquid discharge port; 211. a first inner step; 212. a second inner step; 213. a lubricating oil flow passage; 22. a combination valve; 23. a plunger body; 231. a plunger section; 232. a piston section; 241. a plunger packing assembly; 242. A piston cylinder jacket assembly; 25. a conical sleeve; 26. pressing the sleeve by a valve; 27. a first compression nut; 28. an oil sump; 31. a body; 311. an upper body; 312. a lower body; 32. a sliding sleeve; 320. a third inclined surface; 321. a first spherical pit; 322. A first steel ball; 33. a camshaft; 41. a first bevel cam; 410. a first annular groove; 411. a first slipper member; 4111. a first slipper; 4112. a first slider; 42. a second bevel cam; 420. a second annular groove; 421. a second slipper member; 4211. a second slipper; 4212. a second slide carriage; 43. a first movable chamber; 44. a second movable chamber; 50. A first auxiliary cam; 51. a first inclined surface; 510. a third spherical pit; 511. a third steel ball; 52. a second inclined surface; 520. a second spherical pit; 521. a second steel ball; 60. a second auxiliary cam; 61. a fourth inclined surface; 610. a fourth spherical pit; 611. a fourth steel ball; 71. pressing a sleeve; 72. a medium-pressure sleeve; 73. pressing down the sleeve; 74. a second compression nut; 81. a first sliding bearing; 82. a second sliding bearing; 83. a third sliding bearing; 84. a thrust ball bearing; 85. a submersible motor; 86. a motor flange; 87. connecting sleeves; 88. and (4) oil sealing.
Detailed Description
The present invention will be described in further detail with reference to the following embodiments.
Referring to fig. 1-16, a single-cylinder plunger pump for a submersible well comprises a lubricant oil supply unit, a hydraulic end, a power end and a submersible motor 85, wherein the lubricant oil supply unit, the hydraulic end, the power end and the submersible motor 85 are sequentially connected from top to bottom to form an overall substantially cylindrical structure. Specifically, the lubricant oil storage tank 10, the pump body 21 at the hydraulic end, the machine body 31 at the power end, and the submersible motor 85 of the lubricant oil supply unit are all cylindrical and are connected in sequence to form an integral structure of an integral long cylinder. Specifically, the oil well pump in this embodiment can set the overall outer diameter of the pump according to different well sizes.
Referring to fig. 2, the fluid end of the pump includes a pump body 21, a combination valve 22, a plunger body 23, a plunger packing assembly 241, and a piston-cylinder sleeve assembly 242. The pump body 21 is a cylindrical shell, the upper and lower ends of the pump body 21 are provided with connectors, the connector at the upper end is connected with the bottom joint of the lubricating oil storage tank 10, and the connector at the lower end is connected with the upper body 311 at the bottom and the power end. Specifically, the connection port at the upper end of the pump body 21 is also a drain port 210, and after being fixedly connected to the lubricant reservoir 10, it can communicate with the lower port of the medium delivery pipe 11 built in the lubricant reservoir 10.
With continued reference to fig. 2, the combination valve 22 and the plunger 23 at the hydraulic end are respectively disposed in the pump body 21 one above the other, wherein the combination valve 22 is an integrated structure with a liquid discharge valve above and a liquid inlet valve below, and the structure of the integrated combination valve 22 is the prior art and is not described herein. The plunger body 23 includes a piston section 232 at an upper portion and a plunger section 231 at a lower portion. The plunger packing assembly 241 is disposed at the lower portion of the pump body 21 and correspondingly disposed outside the plunger section 231 of the plunger body 23, and the piston cylinder sleeve assembly 242 is disposed at the upper portion of the pump body 21 and correspondingly disposed outside the piston section 232 of the plunger body 23. The mode that adopts plunger packing to seal and piston cylinder sleeve seal to combine together has realized that the secondary structure is sealed, has further improved the stability of the plunger body 23 reciprocating motion of oil-well pump.
Referring to fig. 2, in order to securely fit the plunger packing assembly 241 and the piston cylinder sleeve assembly 242 in the pump body 21, the pump body 21 further has a first inner step 211 at a lower portion and a second inner step 212 at an upper portion therein. The plunger packing assembly 241 is pressed against the first inner step 211 by the first compression nut 27. A conical sleeve 25 is arranged between the bottom of the valve body of the combination valve 22 and the top of the piston-cylinder sleeve assembly 242, a valve pressing sleeve 26 is further arranged on the upper portion of the valve body of the combination valve 22, and the top of the valve pressing sleeve 26 can be pressed down under the condition that the bottom of the lubricating oil storage tank 10 is connected to the top of the pump body 21, so that the valve pressing sleeve 26, the combination valve 22, the conical sleeve 25 and the piston-cylinder sleeve assembly 242 are axially pressed on the second inner step 212 of the pump body 21 in sequence.
The pump body 21 further has a lubricating oil flow passage 213 and an oil pool 28 communicated with the lubricating oil flow passage 213, wherein the oil pool 28 is correspondingly located between the piston cylinder sleeve assembly 242 and the plunger packing assembly 241. Thus, when the hydraulic end of the oil pump operates, the lubricating oil in the lubricating oil storage tank 10 can effectively lubricate the plunger packing assembly 241 and the piston cylinder sleeve assembly 242 through the lubricating oil flow passage 213 and the oil pool, so as to reduce the friction coefficient, and improve the service life of moving parts such as the plunger section 231, the piston section 232 and the like of the plunger body 23, which is detailed in fig. 2.
Referring to fig. 4, the lubricant oil supply unit includes a lubricant oil reservoir 10 having an oil reservoir chamber 100, and a medium delivery pipe 11 built in the lubricant oil reservoir 10. The lubricant oil reservoir 10 is generally cylindrical, and has an outer diameter substantially equal to the size of the pump body 21, and a length of 1 to 3m is selected. The bottom of the lubricant oil tank 10 is fixedly connected with the top of the pump body 21 by bolts to form an integral structure. The lower end of the medium conveying pipe 11 penetrates through the lubricating oil storage tank 10 and is communicated with the liquid outlet 210 of the pump body 21, the upper end of the medium conveying pipe 11 penetrates through the lubricating oil storage tank 10 to form a liquid outlet pipe opening 110, and the oil storage cavity 100 of the lubricating oil storage tank 10 is communicated with the lubricating oil flow passage 213 of the pump body 21. The liquid outlet pipe mouth 110 of the medium conveying pipe 11 can be connected with a liquid conveying hose 12 through a step screw thread, and the liquid conveying hose 12 can extend upwards to the ground so as to convey underground oil to a ground pipeline. The infusion hose 12 of the present embodiment is a composite pipe structure in which a cable is filled in a wall thickness portion thereof, so that the submersible motor 85 can be electrically connected to a control cabinet on the ground. The cable of the submersible motor 85 is fixed on the outer diameters of the submersible motor 85, the machine body 31, the pump body 21 and the lubricating oil storage tank 10 by clips and then is connected with the electric wire of the composite oil delivery hose, so that the cable and the ground control cabinet interface are connected to form a combined device integrating a mechanical moving part, a power source and a control circuit.
For convenience of production and assembly, the lubricant storage tank 10 in this embodiment may be a three-in-one structure, in which a discharge line connector is provided at a lower portion thereof to be positioned with a step on an upper end surface of the hydraulic pump body 21 and then fixed by a bolt, and a medium transfer pipe portion is provided at a middle portion thereof, the medium transfer pipe portion adopts a two-line fitting structure, wherein a small line located at an inner side constitutes the medium transfer pipe 11 for transferring a medium, the small line and a middle interlayer portion of an outer diameter line form an oil storage cavity 100 for storing lubricant, and a step screw is provided at an upper portion thereof to be connected to the fluid transfer hose 12.
Referring to fig. 3, the power end includes a body 31, a camshaft 33, and a transmission mechanism.
Referring to fig. 5, the body 31 is divided into an upper body 311 and a lower body 312. The body 31 has a cylindrical shape as a whole, and incorporates the camshaft 33 and the transmission mechanism. The top of the body 31 is connected with the pump body 21 at the hydraulic end, and the bottom of the body 31 is connected with the submersible motor 85 through a motor flange 86. A camshaft 33 is rotatably provided in the body 31, and a lower end of the camshaft 33 is connected to an output shaft of the submersible motor 85. Wherein, a connecting sleeve 87 is arranged in the inner hole of the motor flange 86, an inner spline is arranged in the inner hole of the connecting sleeve 87, the lower end of the camshaft 33 and the output shaft of the submersible motor 85 are both external splines and are connected and fixed by the inner spline of the connecting sleeve 87.
The transmission mechanism includes a sliding sleeve 32, a cam assembly, and a compression sleeve assembly. The outer diameter of the sliding sleeve 32 is in a step shape with a small upper part and a big lower part, and specifically can be formed by three sections of cylinders, which are shown in detail in fig. 8. The outer diameter of the sliding sleeve 32 corresponding to the lower cylinder is substantially the same as the outer diameter of the cam assembly. The end surface of the upper cylinder of the sliding sleeve 32 is provided with an inner screw thread for connecting with the lower end of the plunger body 23 at the hydraulic end.
Referring to fig. 3, the lower end of the sliding sleeve 32 is connected with the cam assembly to form an integral member, and is sleeved on the outer side of the cam shaft 33 together, so that the rotary motion of the cam shaft 33 is converted into the up-and-down reciprocating motion of the sliding sleeve 32.
With continued reference to fig. 3, the cam assembly includes at least one set of a main cam member, a first auxiliary cam 50 and a second auxiliary cam 60. The number of the first auxiliary cams 50 is the same as the number (group number) of the main cam members, and one group of the main cam members includes the first inclined surface cam 41 and the second inclined surface cam 42, and the first inclined surface cam 41 and the second inclined surface cam 42 have the same structure. The first inclined cam 41 and the second inclined cam 42 are sleeved on the cam shaft 33 and are matched with the cam shaft 33 in a spline connection mode, so that the first inclined cam and the second inclined cam rotate synchronously with the cam shaft 33. The first inclined cam 41 and the second inclined cam 42 are both provided with an inclined angle as a lift, and the corresponding height of the inclined angle in the axial direction of the cam shaft 33 is the moving stroke of the plunger 23 of the oil well pump of this embodiment, see fig. 11 and 12.
Referring to fig. 9, the first subsidiary cam 50 is provided between the first and second slope cams 41 and 42 of the set of main cam members, respectively. The upper and lower end surfaces of the first auxiliary cam 50 are respectively a first inclined surface 51 and a second inclined surface 52 inclined relative to the axis thereof, wherein the inclination directions of the first inclined surface 51 and the second inclined surface 52 are opposite. The second auxiliary cam 60 is correspondingly arranged below the first auxiliary cam 50, and the upper end surface of the second auxiliary cam 60 is a fourth inclined surface 61 which is consistent with the inclined direction of the second inclined surface 52 of the first auxiliary cam 50, as shown in detail in fig. 10.
Referring to fig. 3, the bottom end of the sliding sleeve 32 and the upper end of the first subsidiary cam 50 are fixedly connected to each other by a dowel pin and a bolt on the outer circumferential side, and similarly, the lower end of the first subsidiary cam 50 and the upper end of the second subsidiary cam 60 are fixedly connected to each other by a dowel pin and a bolt on the outer circumferential side. Above-mentioned structural design has made things convenient for and has assembled between each part of camshaft, sliding sleeve and cam subassembly, has reduced manufacturing cost.
With reference to fig. 3, the bottom surface of the sliding sleeve 32 is a third inclined surface 320 that is consistent with the inclination direction of the first inclined surface 51 of the first auxiliary cam 50, a first movable cavity 43 for accommodating the first inclined cam 41 is reserved between the first inclined surface 51 and the third inclined surface 320, and the first movable cavity 43 can allow the first inclined cam 41 to rotate synchronously with the camshaft 33. A second movable cavity 44 for accommodating the second inclined cam 42 is reserved between the second inclined surface 52 and the fourth inclined surface 61, and the second movable cavity 44 can allow the second inclined cam 42 to synchronously rotate along with the camshaft 33. In a state where the first and second slope cams 41 and 42 are fitted to the camshaft 33, the first and second slope cams 41 and 42 are inclined in opposite directions.
Referring to fig. 3, a first spherical concave point 321 is provided at a lower position of the third inclined surface 320 of the sliding sleeve 32, a first steel ball 322 is disposed in the first spherical concave point 321, a first annular groove 410 (see fig. 12 in detail) coaxially disposed with the first inclined cam 41 is provided on an upper end surface of the first inclined cam 41, a first shoe member 411 capable of moving relative to the first inclined cam 41 is disposed in the first annular groove 410, and the first shoe member 411 is engaged with the first steel ball 322 in the first spherical concave point 321 and fixed relative to the first steel ball 322. The first shoe member 411 specifically comprises a first shoe 4111 and a first sliding base 4112, the bottom of the first shoe 4111 is connected to the first sliding base 4112, the first sliding base 4112 is constrained in the first annular groove 410, and the top of the first shoe 4111 has a ball socket capable of being in rolling fit with the first steel ball 322. When the first inclined cam 41 rotates, the upper end surface of the first inclined cam 41 and the third inclined surface 320 of the slide sleeve 32 are in point contact with each other through the first shoe 411 and the first steel ball 322, so that the slide sleeve can be pushed to move upward. Similarly, the second inclined surface 52 of the first auxiliary cam 50 is provided with a second spherical concave point 520 at the low position, the first spherical concave point 321 is provided with a second steel ball 521, the upper end surface of the second inclined cam 42 is provided with a second annular groove 420 coaxially arranged with the second inclined cam 42, the second annular groove 420 is provided with a second slipper piece 421 capable of moving relative to the second inclined cam 42, and the second slipper piece 421 is matched on the second steel ball 521 in the second spherical concave point 520 and is fixed relative to the second steel ball 521. The second slipper piece 421 specifically comprises a second slipper 4211 and a second sliding seat 4212, the bottom of the second slipper 4211 is connected to the second sliding seat 4212, the second sliding seat 4212 is constrained in the second annular groove 420, and the top of the second slipper 4211 is provided with a ball socket capable of being in rolling fit with the second steel ball 521. When the second inclined cam 42 rotates, the upper end surface of the second inclined cam 42 and the second inclined surface 52 of the first auxiliary cam 50 are in point contact connection through the second shoe member 421 and the second steel ball 521, and the first auxiliary cam (the sliding sleeve and the first auxiliary cam are fixedly connected into a whole) is synchronously driven to move upwards.
The lower position of the first inclined surface 51 of the first auxiliary cam 50 is provided with a third spherical pit 510 (see fig. 9 in detail), a third steel ball 511 is arranged in the third spherical pit 510, and the lower end surface of the first inclined cam 41 directly abuts against the third steel ball 511, so that point contact connection between the lower end surface of the first inclined cam 41 and the first inclined surface 51 of the first auxiliary cam 50 is formed. Similarly, a fourth spherical concave point 610 (see fig. 10 in detail) is provided at a lower position of the fourth inclined surface 61 of the second auxiliary cam 60, a fourth steel ball 611 is disposed in the fourth spherical concave point 610, and a lower end surface of the second inclined cam 42 abuts against the fourth steel ball 611, thereby forming a point contact connection between the lower end surface of the second inclined cam 42 and the fourth inclined surface 61 of the second auxiliary cam 60. When the first inclined cam 41 and the second inclined cam 42 rotate, the third steel ball and the fourth steel ball act on the integrated member formed by combining the sliding sleeve, the first auxiliary cam and the second auxiliary cam, so that the downward movement resetting action of the sliding sleeve is realized.
Because the first inclined plane cam 41 and the second inclined plane cam 42 are opposite in inclination direction in the state that the first inclined plane cam 41 and the second inclined plane cam 42 are assembled on the camshaft 33, and the point contact connection position between the upper end surface of the first inclined plane cam 41 and the third inclined plane 320 of the sliding sleeve 32 and the point contact connection position between the upper end surface of the second inclined plane cam 42 and the second inclined plane 52 of the first auxiliary cam 50 are respectively located on both sides of the camshaft 33, when the camshaft 33 drives the first inclined plane cam 41 and the second inclined plane cam 42 to rotate, the radial acting forces of the sliding sleeve 32 and the corresponding plunger body 23 can be mutually offset, the forward resistance thereof is greatly reduced, therefore, the sliding sleeve can smoothly move axially backwards, the problem of rapid abrasion of each part is avoided, and the frequency of maintenance and replacement after the oil well pump is frequently lifted is further reduced.
Referring to fig. 3, the pressing sleeve assembly further includes an upper pressing sleeve 71, a middle pressing sleeve 72 and a lower pressing sleeve 73, which are sequentially sleeved on the camshaft 33 from top to bottom and can synchronously rotate along with the camshaft 33. The upper pressing sleeve 71, the middle pressing sleeve 72 and the lower pressing sleeve 73 are connected with the camshaft 33 through splines. Specifically, the upper end of the lower pressing sleeve 73 abuts against the lower end surface of the second inclined cam 42, the upper end and the lower end of the middle pressing sleeve 72 abut against the lower end surface of the first inclined cam 41 and the upper end surface of the second inclined cam 42, respectively, the lower end of the upper pressing sleeve 71 abuts against the upper end surface of the first inclined cam 41, and the upper end of the camshaft 33 further locks the upper pressing sleeve 71, the first inclined cam 41, the middle pressing sleeve 72, the second inclined cam 42 and the lower pressing sleeve 73 on the camshaft 33 downwards through the second pressing nut 74. The sliding sleeve, the first auxiliary cam and the second auxiliary cam are correspondingly sleeved outside the upper pressing sleeve, the middle pressing sleeve and the lower pressing sleeve, and gaps are reserved between the sliding sleeve, the first auxiliary cam and the second auxiliary cam and the peripheral walls of the corresponding pressing sleeves. The above-mentioned pressing sleeve assembly is provided to space the first and second inclined cams 41 and 42 and firmly fix them on the cam shaft 33.
In order to ensure stability of the camshaft 33 during rotation and the sliding sleeve 32 during up-and-down reciprocating movement, a lower portion of the camshaft 33 is fitted to a lower portion of the body 31 through a first sliding bearing 81 and a thrust ball bearing 84. Specifically, the upper portion of the lower body 312 is provided with a cylindrical inner hole for positioning the first sliding bearing 81 to position the camshaft 33 in the radial direction, and two thrust ball bearings 84 and an oil seal 88 are arranged between the positioning screw thread of the motor flange 86 and the first sliding bearing 81 to position the camshaft 33 in the axial direction. The upper portion of the camshaft 33 is fitted in the inner hole of the lower end of the sliding sleeve 32 by a second sliding bearing 82, and the upper end portion of the sliding sleeve 32 is also fitted in the upper portion of the body 31 by a third sliding bearing 83.
The submersible single-cylinder plunger oil pump of the embodiment has the advantages that: firstly, the oil well pump is a multi-connection combined single-cylinder plunger oil well pump which combines and assembles the submersible motor 85, the power end, the hydraulic end and the lubricating oil storage tank 10 into a whole, wherein the lubricating oil supply unit is arranged at the top of the oil well pump, so that the plunger body 23 and the corresponding packing component or cylinder sleeve component can be effectively lubricated, the dry friction damage of the plunger body 23 is avoided, the well lifting maintenance frequency is reduced, and the production cost is reduced. Secondly, the lubricating oil storage tank 10 of the lubricating oil supply unit is directly assembled at the top of the pump body 21, so that the whole oil well pump is of a roughly cylindrical structure, oil discharged from the hydraulic end of the oil well pump is upwards discharged through a medium conveying pipe 11 arranged in the lubricating oil storage tank 10, the structural design enables the whole structure of the oil well pump to be more reasonable in arrangement, the size is reduced, and the oil well pump can be better used in a vertical well, an inclined well and a low-yield well. Moreover, the first inclined cam 41 and the second inclined cam 42 at the power end are assembled on the camshaft 33, the inclination directions of the two cams are opposite, and the point-contact connection position between the upper end surface of the first inclined cam 41 and the third inclined surface 320 of the sliding sleeve 32 and the point-contact connection position between the upper end surface of the second inclined cam 42 and the second inclined surface 52 of the first auxiliary cam 50 are respectively located at two sides of the camshaft 33, so that when the camshaft 33 drives the first inclined cam 41 and the second inclined cam 42 to rotate, the radial acting forces of the sliding sleeve 32 and the corresponding plunger body 23 can be mutually offset, the forward resistance thereof is greatly reduced, and therefore, the axial reciprocating movement can be smoothly performed, the problem of rapid abrasion of each part is avoided, and the maintenance and replacement frequency after the oil well pump is frequently lifted is further reduced.

Claims (10)

1. The submersible single-cylinder plunger oil pump comprises a hydraulic end, a power end and a submersible motor (85), and is characterized by further comprising a lubricating oil supply unit, wherein the lubricating oil supply unit, the hydraulic end, the power end and the submersible motor (85) are sequentially connected and combined from top to bottom to form an overall approximately cylindrical structure;
the power end includes:
the body (31) is cylindrical, the top of the body (31) is connected with the pump body (21) at the hydraulic end, and the bottom of the body (31) is connected with the submersible motor (85);
a camshaft (33) rotatably provided in the body (31), a lower end of the camshaft (33) being connected to an output shaft of the submersible motor (85);
the transmission mechanism can be constrained in the machine body (31) in a vertically sliding manner and comprises a sliding sleeve (32) and a cam assembly, the upper end of the sliding sleeve (32) is connected with the plunger body (23) at the hydraulic end, the lower end of the sliding sleeve (32) is connected with the cam assembly to form an integral piece, the integral piece is sleeved on the outer side of the camshaft (33), and the rotary motion of the camshaft (33) can be converted into the vertical reciprocating motion of the sliding sleeve (32);
the fluid end includes:
the pump body (21) is a cylindrical shell, the top of the pump body is provided with a liquid outlet (210), the bottom of the pump body is connected with the machine body (31) at the power end, and the pump body (21) is also provided with a lubricating oil flow channel (213);
a combination valve (22) and a plunger body (23) which are respectively arranged in the pump body (21) from top to bottom, wherein the combination valve (22) adopts an integrated structure that a liquid discharge valve is arranged on the top and a liquid inlet valve is arranged on the bottom;
the lubricating oil supply unit comprises a lubricating oil storage tank (10) with an oil storage cavity (100) and a medium conveying pipe (11) arranged in the lubricating oil storage tank (10) in a built-in mode, the lubricating oil storage tank (10) is integrally cylindrical, the bottom of the lubricating oil storage tank (10) is connected with the top of a pump body (21) to form an integral structure, the lower end of the medium conveying pipe (11) penetrates out of the lubricating oil storage tank (10) and is communicated with a liquid discharge port (210) of the pump body (21), the upper end of the medium conveying pipe (11) penetrates out of the lubricating oil storage tank (10) to form a liquid outlet pipe opening (110), and the oil storage cavity (100) of the lubricating oil storage tank (10) is communicated with a lubricating oil flow channel.
2. The submersible single cylinder plunger pump according to claim 1, wherein: the device also comprises an infusion hose (12) which is connected to the liquid outlet pipe orifice (110) of the medium conveying pipe (11) and extends to the ground, and the infusion hose (12) is of a composite pipeline structure filled with electric cables.
3. The submersible single cylinder plunger pump according to claim 1, wherein: the hydraulic end comprises a plunger packing assembly (241) and a piston cylinder sleeve assembly (242) besides the pump body (21), the combination valve (22) and the plunger body (23), the plunger body (23) comprises a piston section (232) located at the upper part and a plunger section (231) located at the lower part, the plunger packing assembly (241) is arranged at the lower part of the pump body (21) and correspondingly sleeved outside the plunger section (231) of the plunger body (23), the piston cylinder sleeve assembly (242) is arranged at the upper part of the pump body (21) and correspondingly sleeved outside the piston section (232) of the plunger body (23), an oil pool communicated with the lubricating oil flow passage (213) is further arranged on the pump body (21), and the oil pool is correspondingly located between the piston cylinder sleeve assembly (242) and the plunger packing assembly (241).
4. The submersible single cylinder plunger pump according to claim 3, wherein: the pump body (21) is internally provided with a first inner step (211) at the lower part and a second inner step (212) at the upper part, and the plunger packing assembly (241) is pressed on the first inner step (211) through a first pressing nut (27);
a conical sleeve (25) is arranged between the bottom of the valve body of the combination valve (22) and the top of the piston cylinder sleeve assembly (242), a valve pressing sleeve (26) is further arranged on the upper portion of the valve body of the combination valve (22), and the valve pressing sleeve (26), the combination valve (22), the conical sleeve (25) and the piston cylinder sleeve assembly (242) are pressed on the second inner step (212) in sequence under the condition that the bottom of the lubricating oil storage tank (10) is connected to the top of the pump body (21).
5. The submersible single cylinder plunger pump according to any of claims 1-4, wherein the cam assembly comprises:
at least one group of main cam pieces, which comprises a first inclined plane cam (41) and a second inclined plane cam (42), wherein the first inclined plane cam (41) and the second inclined plane cam (42) are sleeved on the cam shaft (33) and can synchronously rotate along with the cam shaft (33), and the inclination directions of the first inclined plane cam (41) and the second inclined plane cam (42) are opposite when the first inclined plane cam (41) and the second inclined plane cam (42) are assembled on the cam shaft (33);
the first auxiliary cam (50) is consistent with the number of the main cam pieces and is correspondingly arranged between a first inclined plane cam (41) and a second inclined plane cam (42) of one group of main cam pieces, the upper end surface and the lower end surface of the first auxiliary cam (50) are respectively a first inclined plane (51) and a second inclined plane (52) which are inclined relative to the axis of the first auxiliary cam, wherein the inclined directions of the first inclined plane (51) and the second inclined plane (52) are opposite, the upper end of the first auxiliary cam (50) is fixedly connected with the bottom end of the sliding sleeve (32), the bottom surface of the sliding sleeve (32) is a third inclined plane (320) which is consistent with the inclined direction of the first inclined plane (51) of the first auxiliary cam (50), and a first movable cavity (43) for accommodating the first inclined plane cam (41) is reserved between the first inclined plane (51) and the third inclined plane (320), the upper end surface of the first inclined cam (41) and the third inclined surface (320) of the sliding sleeve (32) and the lower end surface of the first inclined cam (41) and the first inclined surface (51) of the first auxiliary cam (50) are in point contact connection;
and the second auxiliary cam (60) is correspondingly arranged below the first auxiliary cam (50) and fixedly connected with the first auxiliary cam (50), the upper end surface of the second auxiliary cam (60) is a fourth inclined surface (61) consistent with the inclined direction of the second inclined surface (52) of the first auxiliary cam (50), a second movable cavity (44) used for accommodating the second inclined surface cam (42) is reserved between the second inclined surface (52) and the fourth inclined surface (61), and the upper end surface of the second inclined surface cam (42) and the second inclined surface (52) of the first auxiliary cam (50) as well as the lower end surface of the second inclined surface cam (42) and the fourth inclined surface (61) of the second auxiliary cam (60) are in point contact connection.
6. The submersible single cylinder plunger pump according to claim 5, wherein: a first spherical concave point (321) is arranged at the lower position of a third inclined surface (320) of the sliding sleeve (32), a first steel ball (322) is arranged in the first spherical concave point (321), and the upper end surface of the first inclined cam (41) is directly or indirectly abutted against the first steel ball (322), so that point contact connection between the upper end surface of the first inclined cam (41) and the third inclined surface (320) of the sliding sleeve (32) is formed;
a second spherical concave point (520) is arranged at the lower position of a second inclined surface (52) of the first auxiliary cam (50), a second steel ball (521) is arranged in the first spherical concave point (321), and the upper end surface of the first inclined surface cam (41) is directly or indirectly abutted against the second steel ball (521), so that point contact connection between the upper end surface of the second inclined surface cam (42) and the second inclined surface (52) of the first auxiliary cam (50) is formed;
a third spherical concave point (510) is arranged at the lower position of the first inclined surface (51) of the first auxiliary cam (50), a third steel ball (511) is arranged in the third spherical concave point (510), and the lower end surface of the first inclined surface cam (41) is abutted against the third steel ball (511), so that point contact connection between the lower end surface of the first inclined surface cam (41) and the first inclined surface (51) of the first auxiliary cam (50) is formed;
a fourth spherical concave point (610) is arranged at the lower position of a fourth inclined surface (61) of the second auxiliary cam (60), a fourth steel ball (611) is arranged in the fourth spherical concave point (610), and the lower end surface of the second inclined surface cam (42) is abutted against the fourth steel ball (611), so that point contact connection between the lower end surface of the second inclined surface cam (42) and the fourth inclined surface (61) of the second auxiliary cam (60) is formed.
7. The submersible single cylinder plunger pump according to claim 6, wherein: a first annular groove (410) which is coaxial with the first inclined cam (41) is formed in the upper end face of the first inclined cam (41), a first sliding shoe piece (411) which can move relative to the first inclined cam (41) is arranged in the first annular groove (410), and the first sliding shoe piece (411) is matched on a first steel ball (322) in a first spherical concave point (321);
the upper end face of the second inclined cam (42) is provided with a second annular groove (420) which is coaxial with the second inclined cam (42), a second sliding shoe piece (421) which can move relative to the second inclined cam (42) is arranged in the second annular groove (420), and the second sliding shoe piece (421) is matched on a second steel ball (521) in a second spherical concave point (520).
8. The submersible single cylinder plunger pump according to claim 5, wherein: still include that top-down overlaps in proper order and establishes on camshaft (33) and can follow camshaft (33) synchronous rotation's last pressure cover (71), well pressure cover (72) and press cover (73) down, the upper end of pressing cover (73) down supports on the lower terminal surface of second inclined plane cam (42), the upper and lower both ends of well pressure cover (72) support respectively the lower terminal surface of first inclined plane cam (41) and the up end of second inclined plane cam (42) offset, the lower extreme of going up pressure cover (71) supports on the up end of first inclined plane cam (41), the upper end of camshaft (33) still will go up through second gland nut (74) and press cover (71), first inclined plane cam (41), well pressure cover (72), second inclined plane cam (42) and press cover (73) to lock on camshaft (33) down.
9. The submersible single cylinder plunger pump according to claim 8, wherein: the upper pressing sleeve (71), the first inclined surface cam (41), the middle pressing sleeve (72), the second inclined surface cam (42) and the lower pressing sleeve (73) are connected with the cam shaft (33) in a spline mode.
10. The submersible single cylinder plunger pump according to claim 5, wherein: the lower part of the camshaft (33) is matched with the lower part of the machine body (31) through a first sliding bearing (81) and a thrust ball bearing (84), the upper part of the camshaft (33) is matched with the inner hole at the lower end of the sliding sleeve (32) through a second sliding bearing (82), and the upper end part of the sliding sleeve (32) is also matched with the upper part of the machine body (31) through a third sliding bearing (83).
CN202021133095.1U 2020-06-17 2020-06-17 Submersible single-cylinder plunger oil pump Active CN212898899U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021133095.1U CN212898899U (en) 2020-06-17 2020-06-17 Submersible single-cylinder plunger oil pump

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021133095.1U CN212898899U (en) 2020-06-17 2020-06-17 Submersible single-cylinder plunger oil pump

Publications (1)

Publication Number Publication Date
CN212898899U true CN212898899U (en) 2021-04-06

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ID=75280203

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202021133095.1U Active CN212898899U (en) 2020-06-17 2020-06-17 Submersible single-cylinder plunger oil pump

Country Status (1)

Country Link
CN (1) CN212898899U (en)

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