RU2317445C1 - Submersible multistage modular centrifugal pump - Google Patents

Abstract

FIELD: oil producing industry.

SUBSTANCE: invention relates to submersible centrifugal electric pumping plants. Proposed submersible pump contains number of similar module sections whose shafts are successively connected by splined couplings. Each module-section has housing with fitted-in packs of stages consisting of impeller and guide vane assembly, and base which is turned into housing of module-section. Detachable radial sliding bearing with axial channels to pass handles liquid is installed in base housing without clearance, and outer cylindrical groove is made. Detachable radial sliding bearing has hub arranged in center of housing of radial sliding bearing and provided with conical faces on end faces, shifted forward to side opposite to direction of liquid flow through 1/3 of its length relative to housing of radial sliding bearing. Hub is secured in housing of radial sliding bearing by four blades playing part of stiffening ribs and provided with rounded off profiles of front and rear parts. Blades are installed at tilting through 45° relative to vertical plane of end face and axis of housing of radial sliding bearing and are arranged at circumference being spaced through 90°.

EFFECT: reduced radial runout of lower end of shaft and radial vibration and hydraulic resistances in lower radial sliding bearing at inlet of liquid into first impeller of pump nodule-section.

5 dwg

Description

The invention relates to techniques for the selection of fluid from deep wells, in particular to submersible centrifugal electric pump units designed for oil production from wells.

Known pumping unit containing a submersible motor with hydraulic protection, pump module sections having clamping plates connected in series with each other, input module and module head [Oilfield equipment. Reference / edited by E.I. Bukhalenko - M., Nedra, 1990. - S.124-127]. The connection of the module housings is flanged with bolts, and the connection of the shafts with the help of splined couplings.

A disadvantage of the known design of modular design is the low resistance to vibration, leading to a decrease in the durability and performance of the pump, and increased hydraulic resistance at the fluid inlet to the pump section, which reduces the efficiency of operation of pumping units.

The closest technical solution is the design of the pump module section, which represents the housing, inside of which there is an assembly of pump stages, consisting of guiding devices, fixedly fixed due to the end interference on one side of the upper radial bearing housing, and on the other hand, the base screwed onto the thread with the outer bolt flange [Installation of equipment and repair of borehole electric pumps. Reference book / S.A. Makhmudov, M.S. Abuzorli. - M., Nedra, 1995. - S.50-51].

The shaft of the module-section of the pump with steps installed on it, in which the impellers are located, rotating on the radial bearings of the hubs of the guide vanes. One end of the shaft is located in the hub of the upper radial sliding bearing, and the other in the hub of the lower radial sliding bearing, the housing of which is installed between the guide apparatus of the first stage of the pump and the base screwed into the housing of the module section. The lower radial plain bearing is a cylindrical housing with axial openings for the flow of the pumped liquid and the cylindrical hub, inside which a hollow sleeve (liner) is pressed in, forming a protective sleeve fixed to the pump shaft with a key, a radial sliding support. The inner surface of the hub with the liner is a radial shaft bearing, and the outer cylindrical surface of the housing is a radial support, which receives the load from the pump shaft and transfers the module section to the housing.

The disadvantages of this design of the pump module module can be attributed, firstly, to the fact that the end lower part of the shaft has a radial support located at a considerable distance from the joint point with a spline coupling; secondly, the presence of a radial clearance between the inner surface of the housing of the module section and the outer cylindrical surface of the housing of the lower radial bearing, which is a radial support; thirdly, the implementation of the hub of the radial bearing of significant radial thickness (associated with the need to extrude the assembly of the package of steps with the shaft when disassembling the pump) and having an end surface located perpendicular to the fluid flow from the side of the inlet to the pump section, which is a source of increased hydraulic resistance; fourthly, the large length of the base housing due to the clamping plates mounted on it for fastening the cable, which leads to an increase in the length of the cantilever part of the pump shaft.

The first and fourth circumstances lead to the fact that the free lower cantilever end of the shaft has an unreasonably long part, which, having low stiffness, deviates from the axis of rotation during operation of the pump, causing radial runouts under the action of centrifugal forces from the imbalance of the spline coupling rotating on the free end. As a result, the resulting radial vibration causes premature wear of the radial bearings, resulting in reduced durability and loss of pump performance.

The second circumstance, consisting in the presence of a radial clearance between the outer cylindrical surface of the bearing housing, leads to an additional source of radial vibration of the lower end of the shaft. The cylindrical outer surface of the bearing housing touches the housing of the module section and one-sided, creating a double diametrical clearance on the opposite side, thus providing the possibility of misalignment of the bearing and radial displacement of the lower end of the pump shaft.

The dynamic imbalance of the assembly "shaft - impellers" and "shaft end - spline coupling" creates radial runouts in the hub of the lower radial bearing, the housing of which, without having a rigid mount with the housing of the module section, increases the radial vibration of the pump, resulting in a sharp decrease in durability and loss of operability of the pump unit. The third circumstance causes an increase in hydraulic resistance to fluid flow at the entrance to the first stage of the module-section of the pump.

The objective of the invention is to increase the efficiency and effectiveness of the pump.

The technical result is to reduce the radial runout of the lower end of the shaft and, consequently, the radial vibration, as well as the hydraulic resistance in the lower radial bearing when fluid enters the first impeller of the pump module section.

The specified technical result is achieved by the fact that the submersible multistage modular centrifugal pump contains a number of similar module sections, the shafts of which are sequentially interconnected by means of splined couplings, each module section has a housing in which stage packages consisting of an impeller and a guide apparatus are installed, and the base, which is screwed onto the module of the section in the housing, in the base housing is installed without a gap, a removable radial plain bearing with axial channels for passage is pumped my fluid. A feature of a submersible multistage modular centrifugal pump is that an external cylindrical groove is made in the base body, forming a vertical flange on one side and a conical section on the other side, which ensures the transition from the smaller to the outer diameter of the base body while maintaining the condition of equal strength of cylindrical and conical on the inclined transition section parts of the base housing, a removable radial plain bearing has a hub with conical chamfers at the ends located in the center HTPE bearing housing and push forward in the opposite direction of fluid flow at 1/3 of its length in relation to the bearing housing. The hub is fixed to the bearing housing with four blades that act as stiffeners and are guides for fluid flow, having rounded profiles of the front and rear parts and installed with a slope of 45 degrees relative to the vertical plane of the end face and axis of the bearing housing 90 degrees to each other around the circle, and the bearing housing is fixed from axial displacement on the one hand with an emphasis on the end protrusion of the base housing and the locking ring, and on the other hand, without end contact with the guide pump apparatus.

The causal relationship between the existing features of the invention and the claimed technical result is as follows.

An inner cylindrical groove with a diameter equal to the outer diameter of the stationary part of the lower radial bearing housing is turned into the base housing from the steps of the module section to a depth equal to the axial length of the lower radial bearing housing, with the formation of an end surface that fixes the axial location of the lower radial bearing. At the opposite end of the cylindrical groove, an annular groove is made into which a retaining ring is mounted to prevent axial displacement of the lower radial bearing in the base housing.

A hub with a fixed sleeve pressed inside it forms a radial sliding support with a sleeve fixed to the shaft by a keyed connection. The axial displacement of the sleeve on the pump shaft from the side of the impeller of the first stage is limited by the spacer sleeve, on the opposite side by a retaining ring in the annular groove of the shaft.

In order to reduce hydraulic resistance and form a twisting of the fluid flow at the entrance to the impeller of the first stage, the hub is placed in the center of the lower radial bearing housing on four blades, which act as stiffeners and are guides for the fluid flow, set 90 degrees apart from each other and 45 degrees to the axis of the housing of the lower radial bearing, with each blade having a rounded profile of the front and rear, and the ends of the hub on both sides are conical chamfers.

To reduce the longitudinal length of the cantilever part of the pump shaft, the hub is extended by one third of its axial length L relative to the front end of the lower radial bearing housing, and the blades fastening it have a slope in degrees when changing from the outer diameter of the hub to the inner diameter of the lower radial bearing housing.

Figure 1 shows a General view of the pump unit with module sections.

Figure 2 shows a General view of the lower part of the module section of a submersible multistage modular centrifugal pump with a lower removable radial plain bearing.

Figure 3 shows the profile of the blades around the circumference.

Figure 4 shows the profile and location of the blades around the circumference and relative to the axis of the sliding bearing with the hub extended towards the fluid inlet and the shape of the conical bevel at the end.

Figure 5 shows the base body indicating the main surfaces.

Submersible multistage modular centrifugal pump consists of a number of similar module sections 1, the shafts 2 of which are connected in series by means of splined couplings.

Each module section has a housing 3, in which packages of steps are installed, consisting of an impeller 4 and a guide apparatus 5 and a base 6, which is screwed onto the housing 3. A removable radial plain bearing 7 with axial channels is mounted without clearance in the base housing 6 for the passage of the pumped fluid, secured by a snap ring 8 on one side and against the end protrusion 9 of the base housing 6 on the other hand.

In the base case 6, made without clamping plates, an external cylindrical groove 11 is made, forming a vertical flange 12 on one side and a conical section 13 on the other side, providing a transition from the smaller to the outer diameter of the base case 6. On the side of the module section steps, an internal cylindrical groove is made 14 with a diameter equal to the outer diameter of the stationary part of the removable radial plain bearing 7, to a depth equal to the axial length of the housing of the radial bearing, with the formation of the end protrusion 9.

The stationary housing of the removable radial plain bearing 7 has a hub 16 located in the center extended relative to the housing of the removable radial plain bearing 7 by one third of its axial length L relative to the front end of the housing of the removable radial plain bearing 7 towards the fluid flow. The hub 16 is made with conical chamfers at both ends and secured by four blades 17, each of which is located at an angle of 45 degrees relative to the vertical and the same angle to the axis of the removable radial plain bearing (figure 4). The blades 17 have a rounded profile on the front and rear and are located around the circumference 90 degrees to each other.

A sleeve 18 is pressed inside the hub 16 with a stop in the annular protrusion of the inner surface of the hub 16, forming a slip pair, with a protective sleeve 19 mounted on the shaft 2 by means of a key 20. The protective sleeve 19 is locked from the axial movement by a spring retaining ring 21 and an expansion sleeve 22.

The end part of the housing of the base 6, screwed onto the thread in the housing 3 of the module section, abuts against the end surface of the first guide apparatus 5, creating an end fit to the package of steps in the housing 3 of the pump. To prevent leaks at the junction of the housing 3 and the housing of the base 6 are placed o-rings 23, 24.

Submersible multistage modular centrifugal pump operates as follows.

A submersible multistage modular centrifugal pump is lowered into the well and put into operation. The torque from the electric motor 25 is transmitted through the tread 26 and the input module 27 to the shaft 2. When the shaft 2 is rotated through the key 20, the torque is transmitted to the protective sleeve 19. The resulting radial load of the shaft 2 is transmitted through the protective sleeve 19 to the hub 18 of the hub 16, then the housing of the removable radial plain bearing 7 on the base housing 6.

The absence of a gap between the housing of the removable lower radial plain bearing 7 and the housing of the base 6 reduces radial vibration of the lower end of the shaft 2. Placing the removable lower radial plain bearing 7 inside the housing of the base and the extended hub 16 of the removable lower radial plain bearing 7 reduces the length of the end of the shaft 2, what decreases the radial runout of the end of the shaft 2 with a spline coupling. The design of the blades 17 of the removable lower radial plain bearing 7 reduces the hydraulic resistance due to the rounded ends and the relatively small transverse thickness of the blades 17 and contributes to the formation of fluid flow at the inlet to the first impeller of the pump, because the blades 17 are located at an angle of 45 ° relative to the axis of the shaft 2. Thus, there is a twisting of the fluid flow.

Claims (1)

Submersible multistage modular centrifugal pump containing a number of similar module sections, the shafts of which are sequentially interconnected by means of splined couplings, each module section has a housing in which stage packages consisting of an impeller and a guide apparatus are installed, and a base that is screwed into module-section housing, a removable radial plain bearing with axial channels for the passage of the pumped liquid is installed in the base housing without a gap, characterized in that in the base housing I made an external cylindrical groove, on one side forming a vertical flange, and the other a conical section, providing a transition from the smaller to the outer diameter of the base body while maintaining the condition of equal strength of the cylindrical and conical parts of the base body on an inclined transition section, a removable radial plain bearing has a hub located in the center of the bearing housing with conical chamfers at the ends, extended forward to the opposite side of the fluid flow 1/3 of its length In addition to the bearing housing, the hub is fixed to the bearing housing by four vanes, which act as stiffeners and are guides for fluid flow, having rounded profiles of the front and rear parts, while the vanes are mounted with an inclination of 45 ° relative to the vertical plane of the end face and axis of the bearing housing circumferentially 90 ° to each other, and the bearing housing is fixed from axial movement on the one hand with an emphasis on the end protrusion of the base housing and the locking ring, on the other hand without end contact with the pump guide.

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