EA044021B1 - CENTRIFUGAL MULTISTAGE ELECTRIC PUMP - Google Patents

Description

The invention relates to the field of hydraulic engineering, namely to centrifugal multistage electric pumps, which can be used as main pumps or as submersible pumps. The main version of the electric pump is designed to increase the pressure in the water supply line, and the submersible version of the electric pump is intended to supply water from wells, wells, reservoirs and open reservoirs in water supply systems for the house, garden irrigation and vegetable garden. The expanding need for domestic water supply systems, in particular from wells and wells, and the volume of production of the corresponding equipment requires the expansion of the arsenal and improvement of technical means, especially submersible centrifugal electric pumps designed for this purpose.

A submersible centrifugal electric pump is known, which contains a sleeve-shaped housing with a cover and axial inlet and outlet pipes, a pump including working stages and a shaft, and an electric motor including a rotor mounted on a hollow shaft, a stator mounted on the inner surface of the sleeve, bearings shields, in the bores of which a hollow shaft is installed on the bearings, which serves for the passage of the pumped medium and has an open end on one side and radial holes on the other, while the bearing shields are equipped with seals, and an electric cable, the input seal of which includes a crimp sleeve. In this case, the electric pump is equipped with a spacer bushing installed between the stator and the bearing shield, located on the side of the working stages of the pump, and elastic O-rings. The bearing shields are pressed against the spacer bushing and sleeve by a screw-nut pair, with the screw mounted on a hollow shaft and the nut being able to impact the end of one of the bearings. The bearings on the hollow shaft and in the bores of the shields are installed with the possibility of axial movement until they stop at the limiting element. There are ledges in the bores of the bearing shields on the sides facing the stator to limit the movement of the bearings, and an elastic ring is installed between the bearing and the bore ledge of one of the bearing shields. The cover is made with a threaded hole and an external conical surface and is secured to the sleeve with an elastic O-ring (RU 2198321).

A submersible multistage pump is known, containing stages with guide vanes in which main axial supports made of wear-resistant material, covers and impellers are mounted, each of which has its own additional axial support, which is also a seal separating the suction and discharge cavities, and is made in the form of a protruding at the end of the impeller there is a collar resting on the surface of the cover; a shaft of non-circular cross-section, on which an impeller hub is installed with a clearance fit, the mounting hole of which corresponds to the non-circular cross-section of the shaft, and separating washers made of antifriction material, and the impeller hub is made protruding above the end of the latter from the input side, separating washers are installed on the shaft with the possibility axial movement on both sides of the impeller hub, each of the washers has a hole corresponding to the non-circular cross-section of the shaft, and a thickness less than the axial clearance formed by the end of the hub and the end of the main support; a guide vane with the main axial support is installed in front of the first impeller, the end of which, facing the impeller, forms an axial gap with the separating washer, the size of which is less than the height of the shoulder of the additional impeller support (RU 2234620).

The disadvantages of the above-mentioned known electric pumps are the complexity of the design, insufficient durability and reliability of the pump due to increased internal leaks, the presence of load on the motor housing and the separating membrane from the influence of pressure developed by the pump stages and supplied by the pump.

A known centrifugal multistage electric pump contains an electric motor and pump stages installed in housings, including guide vanes into which axial supports made of wear-resistant material, stage covers and impellers are mounted, each of which has a seal separating the suction and discharge cavities and is made in the form of a protruding the end of the impeller is a collar resting on a sealing element fixed to the stage cover, a non-circular shaft on which impeller hubs, antifriction washers interacting with the axial supports, and a cable are installed according to a fit allowing axial movement, and the electric pump is equipped with a common casing from the front and rear covers, a built-in capacitor box in which the capacitor and connectors for connecting the cable with the windings of the electric motor are located, and the shaft support of the pump part, made in the form of an anti-friction bushing fixed in the front cover, while the electric motor is located on the output side of the pump stages, its the housing is installed in a casing to form an annular channel and an intermediate support, the front bearing shield of the electric motor is sealed with an elastic membrane, and the sealing element fixed to the stage cover is made in the form of a thin-walled ring insert. When the electric pump is made submersible, the entrance to the pump (from the suction side) is made in the form of mesh suction windows in the front cover, and when the electric pump is made as a main one, the entrance to the pump is made in the form of a fitting in the front cover (RU 77652).

A known centrifugal multistage electric pump contains a casing in which an electric motor and pumping units are placed sequentially installed in housings and connected by shafts.

- 1 044021 pennies with impellers, wherein the electric motor is located on the discharge side of the pump stages and is installed in a casing to form an annular channel for the pumped medium, while the electric motor is equipped with an intermediate support and a front bearing shield, sealed with an elastic membrane, and is sequentially mounted on the electric motor shaft two seals: a stepped front cover of the electric motor and a stepped intermediate housing, made with channels for connecting the outer surface of the membrane with the suction side of the pump stages and with channels for connecting the annular channel of the casing with the discharge side of the pump stages. The front cover of the electric motor and the intermediate housing are sequentially placed between the bearing shield of the electric motor and the coupling, wherein the front cover of the electric motor is made with through holes, supported on one side by the membrane to form an annular cavity and is made sealed relative to the motor shaft, the inner wall of the casing and the intermediate housing, which is made in the form of a sleeve with a conical central protrusion supported on the front cover of the electric motor, and sealed relative to the shaft of the latter and connected by a jumper to the conical central protrusion of the peripheral annular sleeve, sealed relative to the intermediate support and support of the pump stage package, and made with axial and radial non-intersecting holes, and the axial holes are connected to the annular channel of the casing and to the discharge side of the stage package, and the radial holes are connected to the suction side of the latter and to the annular cavity formed between the bearing shield membrane and the front cover of the electric motor.

The pumping stages are equipped with guide vanes and axial supports, the impellers have seals separating the suction and discharge cavities, and antifriction washers that interact with the axial supports, while the shaft of the pumping stages is made of non-circular cross-section with the possibility of axial movement of the impellers mounted on it and is equipped with , opposite the electric motor, with a support in the form of an anti-friction bushing. The electric motor shaft bearing is made cast into the bearing shield during casting of the latter. The electric pump is equipped with a built-in capacitor box, which contains a thermal switch, a capacitor and connectors for connecting the cable to the electric motor windings. The axial supports of the pump stages are made of wear-resistant material. The casing is made with front and rear covers, and the anti-friction bushing is fixed in the front cover. The electric pump is equipped with a fitting in the rear cover. The electric motor has a squirrel-cage rotor and an oil-filled housing. The seals of the pump stages are made in the form of thin-walled ring inserts. In the windows of the front cover 5 at the lower flat end of the electric pump, channels can be installed that perform the functions of a filter element and prevent the penetration of large particles into the electric pump, as well as channels for communicating the cavity 33 of the membrane 11 with the environment surrounding the electric pump. The pumped medium enters the mesh holes of the cover 5 (RU 123076, prototype).

The disadvantages of the known submersible electric pump are insufficient durability and reliability, due to the insignificant size of the filter area, which can be implemented in the windows of the front outer cover, i.e. at the suction inlet of the pump, the lack of the possibility of prompt multiple flushing from accumulated blockages without disassembling the electric pump, and the flat shape of the lower end of the electric pump makes it difficult to pass the joints of the well casing pipes or other obstructing parts when installing the electric pump in the operating position due to possible contact with the joints, which prevents expanding the scope of application of the product.

The technical problem to which this technical solution is aimed is to expand the arsenal and increase the efficiency of such technical means that provide water supply from wells, namely, submersible electric pumps.

The technical result achieved through the use of the claimed technical solution is to create an alternative design of a submersible electric pump that supplies water from a well, and also has high reliability and durability due to the large filtration area at the pump inlet, along the entire conical surface of the bandage, carrying an additionally installed cone-shaped mesh filter element, providing the ability to remove and independently wash the bandage with the filter element, and the dome-shaped guide (in some cases conical) shape of the guide bandage with the filter element from the lower end of the electric pump facilitates the passage of the joints of the well casing pipes when the electric pump is immersed without distortions and deformations from touching the joints these pipes.

The essence of the invention is that a centrifugal multi-stage electric pump contains an outer casing in which an electric motor and pump stages with impellers are placed sequentially installed in housings and connected by shafts, front and rear outer covers of the casing on the suction and discharge side of the electric pump, respectively, of which the front the outer cover is made with suction windows of the pumping stages, and the electric motor is located on the discharge side of the pumping stages and is installed in the casing to form an annular channel for the pumped medium, while the electric motor has an intermediate support and a front bearing shield, sealed with an elastic membrane, and at the ends of the electric motor shaft in series mouth

- 2 044021 the stepped front cover of the electric motor and the stepped intermediate housing have been updated, made with channels for connecting the outer surface of the said membrane with the suction side of the pump stages and with channels for connecting the annular channel of the casing with the discharge side of the pump stages, while the electric pump is equipped with a guide installed on the suction side an attachment in the form of a lattice bandage made of smoothly curved ribs converging to the top of the bandage on one side and connected to the annular rim of the bandage on the other side, as well as a streamlined dome-shaped mesh filter element placed inside the bandage, secured by its ring base along the perimeter of the end of the front outer cover and tapering towards its opposite free end.

Preferably, the bandage is made of smoothly curved ribs converging to its apex and connected by an annular rim, forming a dome-shaped frame.

Preferably, the bandage is installed on the front outer cover using an intermediate adapter secured to this cover with screws along the perimeter of the bandage rim, and the mesh filter element is installed on the adapter on a threaded belt and fixed to the top of the bandage with a central screw.

Preferably, the intermediate adapter is made with an installation ring equipped with an internal thread section and with a hollow cone protruding from the ring.

Preferably, the front cover of the electric motor and the intermediate housing are sequentially placed between the bearing shield of the electric motor and the coupling, and the front cover of the electric motor is made with through holes, supported on one side by the membrane to form an annular cavity and is sealed relative to the motor shaft, the inner wall of the casing and the intermediate housing, which is made in the form of a bushing with a conical central protrusion supported on the front cover of the electric motor, and sealed relative to the shaft of the latter and connected by a jumper to the conical central protrusion of the peripheral annular sleeve, sealed relative to the intermediate support and support of the pump stage package, and made with axial and radial non-intersecting holes , and the axial holes are connected to the annular channel of the casing and to the discharge side of the stage package, and the radial holes are connected to the suction side of the latter and to the annular cavity formed between the bearing shield membrane and the front cover of the electric motor.

Preferably, the pumping stages are equipped with guide vanes and axial supports, the impellers have seals separating the suction and discharge cavities, and antifriction washers that interact with the axial supports, while the shaft of the pumping stages is made of non-circular cross-section with the possibility of axial movement of the impellers installed on it.

In fig. 1 shows a submersible centrifugal multistage electric pump, longitudinal section; Fig. 2 - node A according to Fig. 1, in fig. 3 - enlarged fragment in the area of the electric motor shaft seals, in FIG. 4 - stepped intermediate body in volumetric projection, in Fig. 5 - stepped intermediate body front view, Fig. 6 - section A-A according to FIG. 5, in fig. 7 - section B-B according to Fig. 5, in fig. 8 - front outer cover in volumetric projection, in FIG. 9 - bandage adapter in volumetric projection, in FIG. 10 - mesh filter element in volumetric projection, in FIG. 11 - bandage in volumetric projection, Fig. 12 - diagram of liquid flow through the filter element.

Centrifugal multistage electric pump Vodomet contains an electric motor 1, a built-in capacitor box 2 and pump stages 3 (a package of pumping stages) mounted in housings, housed in a single casing 4 and centered by the front and rear outer covers 5, 6 and an intermediate support 7. Electric motor 1 is an oil-filled asynchronous with a squirrel-cage rotor 8 mounted on rolling bearings 9. The front bearing shield 10 of electric motor 1 is sealed with an elastic membrane 11. Bearing 9 is poured into the shield 10 at the time of casting it on an injection molding machine. Thus, the outer ring of bearing 9 is covered with plastic, which ensures its reliable fixation in the bearing shield 10.

The built-in capacitor box 2 is a sealed cavity that serves to accommodate the capacitor 13 and connectors 14 for connecting cables 15 with the windings of the electric motor 1 and the thermal contactor 29. Also in the capacitor box there is a thermal switch 30 mounted on the thermal contactor 29. The shaft 16 of the pump stages 3 is made , preferably of a non-circular cross-section, for example, hexagonal, connected to the shaft 17 of the electric motor 1 by means of a coupling 18. The pump stages 3 include impellers 19 and antifriction washers 20. The impellers 19 of the pump stages are mounted on a hexagonal shaft 16 in a fit that allows axial movement of the impellers 19 during installation, for which the hubs of the impellers 19 have mounting holes,

- 3 044021 corresponding to the non-circular cross-section of shaft 16.

Antifriction washers 20 interact with axial supports made of wear-resistant material, made in the form of ceramic inserts 21, which are mounted in guide vanes 22. Pump stages 3 also include guide vanes 22, between which covers 23 are installed with sealing ring elements on them that are in contact with the working wheels 19. Inserts 21 rest on collars protruding at the ends of the impellers 19 and form seals separating the suction and discharge cavities (not marked). The guide vanes 22 are sealed with radial seals and form a sealed package with the pump stages 3. The package of pumping stages 3, in turn, rests on a support 28, coupled with an intermediate stage housing 26 in which the seal 27 of the pump part is installed. The housing 26 and the front cover 25 of the electric motor 1 together form a system of channels 32, 37, 38. The channels 32 are made to the front cover 25 along its axis. The channels 37, 38 do not intersect with each other and are made in the housing 26, with longitudinal channels 37 along its axis, and channels 38 radially. In the rear cover 6 of the pump there are eyes (not shown) for fastening the cable, as well as sealed inputs (hermetic inputs) for cable 15 of the float switch 31 and the network cable 15. When the pump is designed without a float switch 31, the rear cover 6 is provided with a sealed input only for the network cable 15 An anti-friction sleeve 24 is installed in the front cover 5 of the electric pump, which serves as a support for the shaft 16 of the package of pump stages 3. The front cover 5 has mesh suction windows (not shown) that prevent the penetration of large particles into the electric pump, as well as channels (not shown) for communicating with the cavity 33 membranes 11 with the environment surrounding the electric pump.

The front cover 25 of the electric motor 1 and the intermediate housing 26 are sequentially placed between the bearing shield 10 of the electric motor 1 and the coupling 18, and the front cover 25 of the electric motor 1 is made with through holes 32, supported on one side by the membrane 11 to form an annular cavity 33, and is made sealed relative to shaft 17 of the electric motor 1, as well as the inner wall of the casing 4 and the intermediate housing 26. The housing 26 is made in the form of a sleeve with a conical central protrusion 34, supported on the front cover 25 and sealed relative to the shaft 17. The protrusion 34 is connected by a jumper 35 to the peripheral annular sleeve 36 of the housing 26, sealed relative to the intermediate support 7 and support 28 of the package of pump stages 3. The housing 26 is made with non-intersecting holes 37,38. The holes 37 are made longitudinal (directed parallel to the axis of the housing 26), and the holes 38 (shown in dotted lines in Fig. 3) are made radial relative to the axis of the housing 26. The holes 37 are connected to the annular channel of the casing 4 and to the discharge side of the stage package 3, and the radial holes 38 are connected to the suction side of the latter and to the annular cavity 33 formed between the membrane 11 of the bearing shield 10 and the front cover 25 of the electric motor 1. An essential feature of the Vodomet-Pro pump is the presence of a front cover 25 and an intermediate housing 26 with seals 12.27 placed in a conical protrusion 34, and having different purposes. The seal 27 of the pump part isolates the electric motor 1 from the effects of excess pressure created by the pump stages 3, while the seal 12 of the electric motor 1 seals the electric motor 1 directly and separates on one side its internal volume filled with oil, and on the other only the environment into which electric pump is loaded.

The submersible electric pump is equipped with a streamlined guide nozzle installed on the suction side in the form of a lattice dome-shaped bandage 45 of smoothly curved ribs 47 converging to the top of the bandage on one side and connected to the annular rim 48 of the bandage on the other side, as well as a streamlined mesh filter element 44 placed inside the bandage dome-shaped (equidistant to the ribs 47 of the bandage 45), fixed with its annular base along the perimeter of the end of the front outer cover 5 and tapering to its opposite free end.

A dome-shaped shape means a design with external streamlined outlines that, when moving, provide the least mechanical interaction with the walls of the casing pipe and other resistance to movement of surrounding objects and the environment.

The bandage 45 is made of smoothly curved ribs 47 converging to its top and connected by an annular rim, forming a dome-shaped (in some cases cone-shaped) openwork permeable frame.

The bandage 45 is installed on the front outer cover 5 using an additionally installed intermediate bandage adapter 43, secured to this cover 5 with screws 42 along the perimeter of the bandage rim 48, and the mesh filter element 44 is installed on the adapter 43 on the threaded belt 49 and fixed to the top of the bandage with a central screw 46 In this case, parts 43-44 are based coaxially when installed along the thread.

The intermediate adapter 43 of the bandage is made with an installation ring 50, equipped with a section of internal thread for the band 49, and with a hollow cone 51 protruding from the ring 47 (i.e., with a through channel) for coaxial fixation of the filter element 44 inside the bandage 45 in order to distribute the suction as much as possible over the entire area of filter element 44.

The cover 5 has channels 41 for communicating the cavity 33 of the membrane 11 with the surrounding electric pump

- 4 044021 Wednesday. The mesh filter 44 is threaded into the adapter 43, which in turn is attached to the front cover 5 with screws 42. Before installation, the guide band 45 is attached to the mesh filter 44 using a screw 46. In FIG. 12 dotted lines depict flow lines that could exist in the absence of cone 51 of adapter 43, solid lines entering the filter element from the outside, flow lines formed in the presence of cone 51.

The electric pump works as follows.

The submersible electric pump is lowered into the well casing with the guide nozzle (band 45) down until it is completely immersed. The streamlined shape of the bandage 45 eliminates emergency situations associated with the electric pump hitting the joints of sections of composite casing pipe.

When power is supplied via cable 15 and the electric motor 1 is turned on, the pumped medium enters through the mesh filter element 44 and the internal cavity (through channel) of the cone 51 into the windows 40 of the cover 5 to the suction of the pump stages 3. Then, due to the rotation of the impellers 19 of the pump stages 3, the pumped medium receives the increment of kinetic energy, which is converted into pressure energy in the guide vanes 22. Under pressure through the internal cavity of the support 28, the channel system 37 of the intermediate housing 26 and its gap with the front cover 25 of the electric motor 1, the pumped medium enters the annular channel between the casing 4 and the housings of the electric motor 1 and then into the housing of the capacitor box 2, cooling the electric motor 1, and through a hose connected from the outside, it is directed to the consumer. The radial and axial forces arising during pump operation, in addition to the bearings 9 of the electric motor 1, are perceived by the anti-friction bushing 24. The formation of contact seals between the collars of the impellers 19 of the pump stages 3 and the sealing ring elements of the covers 23 prevents leakage of the pumped medium. The elastic membrane 11 makes it possible to balance the pressure inside and outside the electric motor 1 and relieve the seal 12 of the electric motor 1 from the discharge pressure. The system of channels 32, 37, 38 makes it possible to isolate the bearing shield 10 with bearing 9, the seal 12 of the electric motor 1 and the membrane 11 from the pressure developed by the pump, communicating their cavity 33 with the medium in which the electric pump is immersed.

In this case, the movement of the pumped medium from the injection of pump stages 3 into the annular channel of the casing 4 occurs through holes 37, and the communication of the cavity 33 of the membrane 11 with the environment (suction of stages 3) - through holes 38, 32. The thermal contactor 29 prevents the operation of the electric motor 1 when exceeding the oil temperature in it is more than 75°C. This eliminates the impact of high pressure on the elements of the electric motor 1, located in the same casing 4 with the pump part (stages 3), in particular on the seal 12 and the membrane 11, which improves the reliability and durability of the electric pump. In addition, since the guide vane 22 has its own radial seal, this eliminates leakage of the pumped medium and makes it possible to ensure absolute tightness of the package of pump stages 3. The location of the thermal switch 29, located from the oil-filled volume of the electric motor 1 into the capacitor box 2, increases the reliability of its operation, facilitates diagnostics and repairs electric pump during operation.

The pumped medium enters the holes of the mesh filter element 44, then through the windows 40 of the front cover 5 to the input of the impellers 19 of the pump stages. The presence of cone 51 ensures a more uniform distribution of suction over the entire area of the mesh filter element 44 in such a way that only the area of the mesh filter not adjacent to the lid 5 works for suction, and suction also occurs in the middle - along the liquid flow lines shown graphically in Fig. 12 continuous thin lines from the surrounding space. This ensures the distribution of liquid over the entire surface of the mesh filter element 44 and the most uniform involvement of the filtering area of the filter element 44 in the operation. The cover 5 contains channels 41 for communicating the cavity 33 of the membrane 11 with the environment surrounding the electric pump. The mesh filter 44 is screwed along the thread into the adapter 43, which in turn is attached to the front cover 5 with screws 42. Before installation, the guide band 45 is attached to the mesh filter 44 using a screw 46.

All this is aimed at increasing the reliability and durability of the device as a whole by increasing the filtration area at the inlet to the electric pump over the entire dome-shaped conical area of the additionally installed bandage carrying the cone-shaped mesh of the filter element, providing the possibility of removing and self-washing the bandage with the filter element, and the dome-shaped conical shape of the guide A bandage with a filter element at the lower end of the electric pump facilitates the passage of protruding parts and/or joints of well casing pipes when installing and immersing the electric pump without touching the joints.

Thus, as a result of the implementation of the claimed invention, the arsenal of equipment is expanded due to the creation of an alternative original submersible electric pump, which has high reliability and durability, since it does not allow disruption of the water supply, unauthorized drainage, the possibility of implementing its functions and inexpensive medium and small-scale production.

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Claims (6)

CLAIM 1. A centrifugal multi-stage electric pump containing an outer casing in which an electric motor and pump stages with impellers are installed sequentially in housings and connected by shafts, front and rear outer covers of the casing on the suction and discharge side of the electric pump, respectively, of which the front outer cover is made with suction windows of the pump stages, and the electric motor is placed on the discharge side of the pump stages and installed in a casing to form an annular channel for the pumped medium, while the electric motor has an intermediate support and a front bearing shield, sealed with an elastic membrane, and a stepped front cover is installed sequentially at the ends of the electric motor shaft electric motor and a stepped intermediate housing, made with channels for connecting the outer surface of the said membrane with the suction side of the pump stages and with channels for connecting the annular channel of the casing with the discharge side of the pump stages, characterized in that it is equipped with a guide nozzle installed on the suction side in the form of a lattice bandage of smoothly curved ribs converging to the top of the bandage on one side and connected to the annular rim of the bandage on the other side, as well as a streamlined dome-shaped mesh filter element located inside the bandage, fixed with its annular base along the perimeter of the end of the front outer cover and tapering to its opposite free end. 2. The electric pump according to claim 1, characterized in that the bandage is made of smoothly curved ribs converging to its top and connected by an annular rim, forming a dome-shaped frame. 3. The electric pump according to claim 2, characterized in that the bandage is installed on the front outer cover using an intermediate adapter secured to this cover with screws along the perimeter of the bandage rim, and the mesh filter element is installed on the adapter on a threaded belt and fixed to the top of the bandage with a central screw. 4. The electric pump according to claim 3, characterized in that the intermediate adapter is made with an installation ring equipped with an internal thread section and with a hollow cone protruding from the ring. 5. An electric pump according to any one of claims 2-4, characterized in that the front cover of the electric motor and the intermediate housing are sequentially placed between the bearing shield of the electric motor and the coupling, and the front cover of the electric motor is made with through holes, supported on one side on the membrane to form an annular cavity and is made sealed against the electric motor shaft, the inner wall of the casing and the intermediate housing, which is made in the form of a sleeve with a conical central protrusion supported on the front cover of the electric motor, and sealed against the latter shaft and connected by a jumper to the conical central protrusion of the peripheral annular sleeve, sealed against the intermediate support and supports of the pump stage package, and made with axial and radial non-intersecting holes, the axial holes being connected to the annular channel of the casing and to the discharge side of the stage package, and the radial holes being connected to the suction side of the latter and to the annular cavity formed between the bearing shield membrane and the front motor cover. 6. The electric pump according to claim 5, characterized in that the pump stages are equipped with guide vanes and axial supports, the impellers have seals separating the suction and discharge cavities, and antifriction washers interacting with the axial supports, while the shaft of the pump stages is made of non-circular cross-section with the possibility of axial movement of the impellers installed on it. -