RU2721994C1 - Ioannesyan's drilling pump - Google Patents

Abstract

FIELD: pumps.

SUBSTANCE: invention relates to drilling pumps. Pump includes housing 1, in inlet cavity 4 of which axial steps 8 are installed, and sections 11 containing stator 12 with eccentrically arranged in it hollow rotor 10 are installed in it. Slot 13 interacting with stator surface 12 is movably installed in slots of rotor 10 to divide space between inner surface of stator 12 and outer surface of rotor 10 into suction and discharge chambers. Internal volume of rotor 10 is connected to volume of stator 12 by holes made in rotor 10. Housing 1 is supplemented with an outlet cavity separated from cavity 4 by sealed partition 3. Sections 11 are installed parallel to each other and are connected to walls of housing 1. Inlets of rotors 10 are connected with volume of cavity 4. Holes made in wall of rotor 10 and connecting its inner volume with volume of stator 12 are equipped with check valves. Outlets of stators 12 connect its inner volume with volume of outlet cavity and are located with angular pitch relative to each other. Each rotor 10 is equipped with a gear interacting with a gear installed on shaft 2 of the driving motor.

EFFECT: invention is aimed at increasing efficiency and reducing pulsations of pressure of pumped liquid.

1 cl, 3 dwg

Description

The invention relates to equipment used in the construction, repair and operation of wells for oil and gas production, can be used in both stationary and mobile pumping units for pumping various process fluids into the well at oil and gas producing enterprises.

Known vane pump, which contains a housing located inside the sleeve acting as a stator. The discharge and supply pipes are attached to the housing. Inside the sleeve there is a shaft with grooves in which the gates are located (RU 123863 U1 [1]). A disadvantage of the known device is its low productivity and the presence of pulsations in the pumped liquid.

Known vane pump with volumetric regulation (RU 2396462 [2]). The pump comprises a housing with inlet and outlet openings, a drive shaft with a rotor, radially extending blades located in the rotor with the possibility of sliding. The axis of rotation of the drive shaft is located in the housing eccentrically relative to the axis of the rotor, equipped with blades. A disadvantage of the known device is its low productivity, due to the purpose - small volumes of pumped liquid.

Known rotary vane pump containing a stator located in the housing with the possibility of displacement relative to the axis of rotation of the rotor located inside it to change the eccentricity between them (DE 102009001152 [3]). Slots are made in the rotor, in which spring-loaded blades are placed opposite, in one contact with the stator surface. The stator has inlet and outlet openings provided with valves. A disadvantage of the known device is its low productivity and the presence of pulsations in the pumped liquid.

From the description of EP 0264778 [4], a vane pump is known which comprises a housing with a stator installed therein with an inlet and an outlet valve equipped with a check valve, and a hollow rotor placed with an eccentricity inside the stator, provided with slots in which the slide is movably mounted, which constantly contacts its ends with the surface of the stator and dividing the volume of the stator into the suction and discharge cavities. A disadvantage of the known device is its low productivity and the presence of pulsations in the pumped liquid.

Closest to the claimed in its technical essence is a mud pump, known from the description of the patent RU 2686558 [5]. A well-known pump includes a housing with a stator installed in it with inlet and outlet openings equipped with check valves, a hollow rotor placed with eccentricity inside the stator. The inner space between the outer surface of the rotor and the inner surface of the stator is divided into several identical sections by transverse sealing partitions perpendicular to the longitudinal axis of the rotor, which passes through all sections. Each section is equipped with its own gate. The gates in each section are installed with an angular pitch relative to each other equal to 360 ° / N, where N is the number of sections. The stator surface interacting with the gate is made so that its cross section is a closed fourth-order flat curve, the distance between any two points of which located on a straight line passing through the longitudinal axis of the cylindrical hollow rotor is a constant value equal to the transverse dimension of the gate. The internal volume of the rotor is hydraulically connected to the source of pumped fluid. The internal volume of the rotor in each section is connected to the stator volume by openings made in the wall of the rotor.

The disadvantages of the known pump are not high enough performance, relatively high weight and rather complicated design.

The claimed mud pump is aimed at increasing productivity and reducing pressure pulsations of the pumped fluid while significantly reducing its weight and simplifying the design.

This result is achieved by the fact that the mud pump contains a housing, in the inlet cavity of which axial steps are installed, and several sections located in it, each of which contains a stator with an outlet and a hollow rotor placed with an eccentricity inside each stator, so that it is movably mounted in the grooves made in the rotor, the gate constantly contacts its ends with the stator surface and divides the space between the inner surface of the stator and the outer surface of the rotor into the suction and discharge cavities, and the internal volume of the rotor is connected to the stator volume by holes made in the rotor wall. The housing is supplemented by an exhaust cavity separated from the inlet cavity by a sealed partition, the sections are mounted parallel to each other and connected to the walls of the housing, the inlet openings of the rotors are connected to the volume of the inlet cavity, the openings made in the wall of the rotor and connecting the internal volume of the rotor to the stator volume are equipped with check valves and the outlet openings of the stators connect the internal volume of the stators with the volume of the outlet cavity of the housing and are arranged with an angular pitch relative to each other equal to 360 ° / N, where N is the number of sections, with each rotor equipped with a gear that interacts with the gear mounted on the drive shaft engine with the ratio of the number of teeth on them K _C / K _D = 2n, where K _C is the number of gear teeth on the shaft of the section, K _D is the number of gear teeth on the motor shaft, n is an integer greater than zero.

The indicated result is also achieved by the fact that the means of connecting the sections to the walls of the housing is made in the form of a bolt inserted into an opening in the pump housing and interacting with a bore in the stator housing, while an arcuate plate with a radius of curvature equal to the radius of curvature of the housing is installed under the head of the bolt, and a rubber-metal seal is placed between the pump casing and said plate.

Distinctive features of the claimed pump are:

- addition of the housing to the exhaust cavity, separated from the inlet cavity by a sealed partition;

- sections are installed parallel to each other and connected to the walls of the housing;

- the inlet rotors are connected to the volume of the inlet cavity;

- outlet stators, connect the internal volume of the stators with the volume of the outlet cavity of the housing;

- the outlet openings of the stators are located with an angular pitch relative to each other equal to 360 ° / N, where N is the number of sections;

- each rotor is equipped with a gear interacting with the gear mounted on the shaft of the drive motor;

- the ratio of the number of teeth on the gears is determined by the expression K _C / K _D = 2n where K _C is the number of gear teeth on the shaft of the section, K _D is the number of gear teeth on the motor shaft, n is an integer greater than zero;

- the means for connecting the sections to the walls of the housing is made in the form of a bolt inserted into an opening in the pump housing and interacting with a bore in the stator housing, while an arcuate plate with a radius of curvature equal to the radius of the pump housing and between the pump housing and the said plate is installed under the bolt head a rubber-metal seal is placed.

Supplementation of the housing with an outlet cavity separated from the inlet cavity by a sealed partition is necessary for organizing the total volume into which the pumped liquid from the working sections will be supplied. This will almost completely eliminate the pressure pulsations of the pumped liquid. This will also be facilitated by the placement of sections parallel to each other, as well as the fact that the outlet openings of the stators in different sections are located with an angular pitch relative to each other equal to 360 ° / N, where N is the number of sections.

The latter provides alternate and evenly distributed over time injection of the pumped liquid from the outlet openings of the stators into the outlet cavity of the pump casing. In addition, alternate and evenly distributed over time injection can occur only when, along with the above-mentioned arrangement of the outlet openings of the stators, the same spatial arrangement of the gates with respect to each other will be provided regardless of the speed of rotation of the drive shaft of the pump. This is achieved by the ratio of the number of teeth on the gears of the drive shaft and on the gears mounted on the rotors of the sections and interacting with it. The ratio is determined by the expression K _C / K _D = 2n where K _C is the number of gear teeth on the shaft of the section, K _D is the number of gear teeth on the motor shaft, n is an integer greater than zero. Then the rotor of each section will make half a revolution when the drive shaft completes a whole revolution. And in half a turn, the gate will complete its duty cycle, leading to the discharge of the pumped liquid into the exhaust cavity of the pump housing.

And to ensure the possibility of pumping liquid, the inlet openings of the stators are connected to the volume of the inlet cavity of the pump housing.

At the same time, in order to exclude reactive rotation of the housing due to the operation of the sections, it is advisable to ensure the connection of the stators of the sections with the walls of the housing. It can be provided by any known means - welding, bolting, casting of the pump casing and stators in one piece, etc. It is most advisable to use a bolt for fastening, inserted into the hole in the pump housing and interacting with the bore in the stator housing, while an arcuate plate with a radius of curvature equal to the radius of the housing is installed under the head of the bolt, and a rubber-metal seal is placed between the pump housing and the said plate. This design not only simplifies the assembly of the pump, but also allows for alignment of the sections not only during assembly, but also during operation. In order to completely exclude the influence of reactive forces aimed at the rotation of the housing due to the operation of the sections, it is advisable to fix the housing on a massive frame or foundation using a conventional lunette.

The essence of the claimed pump is illustrated by an example of its implementation and graphic images. In FIG. 1 shows in longitudinal section an advantageous embodiment. In FIG. 2 shows a cross section along section AA in FIG. 1. In FIG. 3 shows a cross section along section BB in FIG. 1.

A preferred embodiment of the pump comprises a housing 1 (an assembly unit comprising two caps, an inlet and an outlet pipe, and a pipe with necessary openings). In the internal space there is a septum 3 sealed along the drive shaft 2, dividing the internal space into the inlet 4 and the outlet 5 of the cavity. In the inlet cavity of the cavity 4, axial steps 8 are installed on the drive shaft of the pump using spacer sleeves 6 and 7 along the shaft 2 and body 1. The openings 9 are made in the sealed partition, in which the hollow rotors 10 are centered (three holes are shown in the drawing), which are an element sections 11. Each hole is eccentric relative to the axis of the stator 12 so that it is movably mounted in the grooves made in the rotor 10, the gate 13 contacts the surface of the stator and divides the space between the inner surface of the stator and the outer surface of the rotor into a suction cavity 14 and a discharge cavity 15. The inner volume of the rotor is connected to the stator volume by an opening 16 provided with a check valve 17 made in the wall of the rotor 10. Sections 11 are installed parallel to each other. The pump casing is fixed in the shell 18 of the lunette 19, which in turn is fixed on the frame 20.

To perceive the reactive moment, a bolt 21 is inserted, inserted into the bore on the stator 12, and an arcuate plate 22, the radius of curvature of which coincides with the radius of the housing 1.

The inlet openings 16 of the rotors are connected to the volume of the suction cavity 14, and the inner opening of the stator 12 connects the internal volume of the stators to the volume of the exhaust cavity 5. Moreover, these openings 16 in one section are offset by an angle relative to the openings in the other section. The angular step between them is selected depending on the number of sections and is equal to 360 ° / N, where N is the number of sections. Each rotor is equipped with gear 23, which interacts with gear 24 mounted on the drive shaft of pump 2 with the ratio of the number of teeth on them K _C / K _D = 2n, where K _C is the number of gear teeth on the rotor shaft of the section, K _D is the number of gear teeth on drive shaft of the pump, n is an integer greater than zero.

The mud pump works as follows: through the suction nozzle of the housing 1, the flushing agent enters the inlet cavity 4, in which the axial stages 8 are located, and due to the rotation of the axial stages driven by the drive shaft of the pump 2, the fluid pressure increases. After passing through all the axial stages 8, the flushing agent enters the hollow rotors 10 of the sections 11. The hollow rotors 10, driven into rotation by the pump drive shaft 2 through gearing 23 and 24, cause the valves 13 to perform reciprocating movements relative to the stator simultaneously with the rotation so that the ends of the gates are in constant contact with the surface of the stator 12. The liquid through the holes 16 provided with non-return valves 17, made in the wall of the rotor 10, enters the suction cavity 14, formed by the space between the inner surface of the stator 12 and the outer surface of the rotor 10, which is such before turning gate to the outlet in the wall of the rotor. After the end of the gate passes through this hole, the cavity becomes an injection cavity 15 connected to the outlet cavity 5. As the gate rotates, the pressure in the cavity increases, and the fluid is forced through the outlet 25 in the stator wall into the outlet cavity 5 in the pump housing 1 and is pumped through the nozzle into well. When the rotor rotates, the cycle repeats.

The proposed mud pump provides an increase in productivity, a decrease in pressure pulsations of the pumped liquid, while significantly reducing the weight of the pump, as well as reducing the cost of its manufacture by eliminating curved parts that are difficult to manufacture. In addition, the pump provides significant outlet pressure while reducing its length.

Claims (2)

1. A mud pump containing a housing, in the inlet cavity of which axial steps are installed, and several sections located in it, each of which contains a stator with an outlet and a hollow rotor placed with eccentricity inside each stator, so that it is movably mounted in grooves made in the rotor, the gate constantly contacts its ends with the stator surface and divides the space between the inner surface of the stator and the outer surface of the rotor into the suction and discharge cavities, and the internal volume of the rotor is connected to the stator volume by openings made in the rotor wall, characterized in that the housing is supplemented with an exhaust cavity , sealed from the inlet cavity by a sealed partition, the sections are mounted parallel to each other and connected to the walls of the housing, the inlet openings of the rotors are connected to the volume of the inlet cavity, the openings made in the wall of the rotor and connecting the internal volume of the rotor to the stator volume are equipped with check valves, and the outlet openings of the stators connect the internal volume of the stators with the volume of the outlet cavity of the housing and are arranged with an angular pitch relative to each other equal to 360 ° / N, where N is the number of sections, with each rotor equipped with a gear that interacts with the gear mounted on the shaft of the drive motor with the ratio of the number of teeth on them K _C / K _D = 2n, where K _C is the number of gear teeth on the shaft of the section, K _D is the number of gear teeth on the motor shaft, n is an integer greater than zero. 2. The mud pump according to claim 1, characterized in that the means for rigidly connecting the sections to the walls of the housing are made in the form of a bolt inserted into an opening in the pump housing and interacting with a bore in the stator housing, while an arcuate plate with a radius of curvature is installed under the bolt head equal to the radius of the casing, and between the pump casing and the plate is placed rubber-metal seal.

Images