RU2309296C1 - Electric pump - Google Patents

Abstract

FIELD: pump engineering.

SUBSTANCE: electric pump comprises asynchronous motor whose housing is rigidly connected with the lid of the pump base and is made of two shields that define a ring space. The space receives magnetic circuit of the stator provided with the exciting winding. The magnetic circuit of the stator is separated by an air space from the magnetic circuit of the rotor with short-circuited windings mounted in the space between the magnetic circuits of the stator. The rotor of the motor is sectional and is made of the central disk and safety clutch made of two clutch members fit on the shaft of the rotor. The disk of the rotor is freely mounted on the cylindrical surfaces of the clutch members. The clutch members engage the rotor disk by means of spring-loaded balls mounted in the axial opening in the hub of the disk and set in the radial grooves made in the ring collars of the clutch members.

EFFECT: reduced sizes and cost.

4 cl, 2 dwg

Description

The invention relates to the fields of pump engineering, in which the production of pumps and pumping units equipped with an electric drive is carried out, in particular scoop electric pumps, structurally combining an electric motor and a scoop pump in a single unit.

It can find application, mainly, when pumping liquefied gases, for example, from a tank to automobile cylinders, or when pumping chemically aggressive liquids, as well as water.

Known scoop electric pump for liquid cooling of electronic equipment [SU 1430600A1 (MOSKALENKO GV), 10/15/1988], containing a cylindrical electric motor, a rotating pump housing connected to the motor shaft by means of a dowel, a scoop fixedly installed in the pump housing, supplying and outlet pipe for the pumped liquid. This scoop pump has increased axial dimensions, which is associated with an independent design of the electric motor and pump, as well as increased resistance of the hydraulic tract. Its narrow technological purpose and the corresponding design do not allow the unit to be used for pumping liquefied gases and aggressive media.

Also known is a scoop pump [SU 1373876 A (VASILIEV V.I. et al.), 02/15/1988] for water and chemically aggressive liquids, in which a rotating pump housing is attached to the end face of a cylindrical-shaped electric motor rotor. The disadvantages of this pump are associated with an insufficiently reliable sealing system. In particular, in the event of a leak in the mechanical seal at the inlet, aggressive fluid can enter the stator winding of the electric motor, which should be excluded to avoid a possible accident.

By technical nature, the closest to the claimed invention is an electric pump scoop unit НЧ-5 / 170-1, manufactured by JSC "Kataysky Pump Plant" [Electric pump unit Н4-5 / 170-1. Passport N 122.593.000 PS, JSC "Kataysky Pumping Plant", 1993].

The electric pump unit consists of a cylindrical asynchronous explosion-proof electric motor and a scoop pump. The electric motor and pump are designed as structurally independent units. The electric motor is mounted on the pump frame using a flange connection, and the motor shaft and the pump shaft are coupled through a safety clutch with rubber fingers, which is mounted on the output end of the motor shaft. The scoop pump of this unit contains a prefabricated internal hollow pump casing with a centrifugal wheel, rigidly connected to the pump shaft, and a scoop mounted inside the rotating casing on a fixed outlet.

When the pump shaft rotates, the pumped liquid enters the channel of the scoop, and from it through the channel in a stationary outlet is discharged and directed as directed. The fluid is supplied to the centrifugal wheel of the pump casing through the central channel in a fixed outlet. To seal the internal cavity of the pump casing, in which the scoop is located, an end graphite seal is used, the movable part of which is fixed to the wall of the rotating casing, and the fixed part (spring-loaded) is installed on the surface of the outlet.

The electric pump unit has several disadvantages, which include its large axial dimensions and weight, which is associated with the independent design of the pump and its electric drive, which is used as a cylindrical electric motor, characterized by large axial dimensions.

The rotating pump housing in the bearing assembly is mounted cantilever, which, in the presence of residual imbalance of the housing having large radial dimensions and mass, increases the level of vibration and worsens the working conditions of the bearings, thereby reducing the service life and reliability of the unit.

The output channels, made in a fixed branch, on which the ladle is fixed, have a narrow passage section, and their interface with the cavity of the discharge pipe is through holes in the branch, oriented perpendicular to the output channels. This leads to an increase in hydraulic resistance and a decrease in efficiency. pump.

Access to the mechanical graphite seal, which seals the central cavity of the pump housing, in which the ladle is located, is difficult, and its visual inspection is impossible, which excludes the possibility of direct control of the quality of the seal. Replacing the seal in the event of its failure requires a large amount of dismantling to gain access to the seal.

The disadvantages of the pump design should also include the complexity of the structural forms of the body parts, which complicates the technology of their manufacture and increases the cost of the pump design.

The noted drawbacks can be avoided if one is guided by the progressive principle of constructive combination [Cherkassky V.M., Romanova T.M., Kaul R.A. Pumps, compressors, fans. - M .: Energia, 1968, p.19-131], which becomes especially preferable if a face-type electric motor is used as an electric pump [RU 2232459 C1 (ORELGTU), July 10, 2004], which is distinguished by small axial dimensions, lower material consumption and additional features for integration into actuators.

The combination of the advantages of a face motor and a scoop pump in a single unit allows to reduce the axial dimensions of the unit, its material consumption, improve the layout and appearance, increase manufacturability, as well as operational and technical indicators of the unit.

The claimed invention solves the problem of creating a compact design of a monoblock scoop electric pump of small dimensions and mass, increasing its operational and technical indicators and reliability while reducing production costs.

The technical result is achieved by the fact that in a scoop-type electric pump combining an asynchronous electric motor in a single unit, comprising a motor housing, a rotor, a rotor shaft, shaft bearings, stator and rotor magnetic circuits, a safety clutch and a self-cooling system, and a scoop pump including a bed, bed side covers , pump shaft, prefabricated, hollow body finned inside, rigidly connected to the pump shaft, shaft bearings, a centrifugal wheel, rigidly mounted on the inside of the body, a scoop mounted in the body cavity a whisker on a fixed outlet, the inlet and outlet nozzles, unlike the prototype, the asynchronous electric motor has an end face design, the motor housing is rigidly attached to the cover of the pump bed and consists of two rigidly interconnected load-bearing shields forming a central annular cavity, inside of which on each carrier the shield by means of fixing supports is fixed along one annular magnetic circuit of the stator with an m-phase field winding, separated by air gaps from the magnetic circuits of the short-circuit rotor windings placed in the cavity between the stator magnetic circuits, and the rotor of the electric motor is prefabricated and includes a central disk on which one ring rotor magnetic circuit is fixed on both sides, and a safety clutch consisting of two half couplings rigidly mounted on the rotor shaft on cylindrical surfaces which the central disk is freely mounted with its mounting hole, and the central disk coupling devices with half-couplings, each of which contains two spring-loaded balls, sized whelping disc hub in the axial bore and within the radial groove of triangular profile formed in the annular collar of the coupling halves adjacent to the disk on opposite sides.

In this case, the rotor shaft of the electric motor and the pump shaft are structurally combined and form a single electric pump shaft, and its thrust bearings are placed in the bores of the side covers of the pump bed, and an additional bearing is installed on the end section of the shaft from the motor side, located in the end bore of the flange attached to the external bearing shield of the motor housing.

The shaft of the electric pump is hollow, and its central axial channel is interfaced with the cavity of the centrifugal pump wheel and the inlet of the inlet pipe, and the inlet pipe is mounted on the cover of the outer supporting shield of the motor housing and is equipped with a rigidly connected supply sleeve that is included in the central axial channel of the pump shaft and is separated from the surface of the shaft with a seal located in the annular gap between the shaft and the sleeve.

The self-cooling system of the electric motor is made combined and includes structural elements in the form of blades made on the ends of the flanges of the coupling halves of the safety clutch and on the outer surface of the central rotor disk, a fan wheel mounted on the end of the electric pump shaft and placed in the cavity between the outer supporting shield of the electric motor housing and attached to it a cover with an inlet pipe provided with ventilation holes, and a network of ventilation ducts formed outside the finned rpusa motor through the casing covering the housing rib.

The central annular cavity of the motor housing is protected from penetration of the pumped liquid from the side of the inner side cover of the pump bed by the labyrinth-groove seal of the pump shaft, made in the cover and flange attached to the cover and holding the shaft bearing from axial displacement, and from the inlet side by a combined shaft seal represented by grooves in the outer supporting shield of the motor housing and the edge of the flange attached to the shield, in the end bore of which is placed an additional bearing of the electric pump shaft, in combination with a sleeve mounted on the shaft and placed in the bore of the shield on the side of the flange rib.

The invention is illustrated by drawings.

Figure 1 shows a view of the electric pump from the side of the outlet pipe.

Figure 2 is a longitudinal section thereof.

The motor housing consists of two load-bearing shields 1 and 2, rigidly connected to each other and forming a central annular cavity. On the inner sides of the shields 1 and 2, the stator magnetic circuits 3 and 4 are installed with m-phase field windings having a ring shape. The magnetic cores 3 and 4 are fastened using fixing supports 5 and 6, rigidly connected to the magnetic cores through adjusting shims 7 and 8, which serve to set the air gap between the planes of the magnetic circuits 3, 4 of the stator and magnetic circuits 9, 10 of the rotor.

The magnetic circuits 9, 10 of the rotor also having an annular shape, are equipped with short-circuited windings and are rigidly fixed in the annular bores of the Central disk 11 of the rotor. The disk 11 with its seating hole is freely mounted on the cylindrical surfaces of the coupling halves 12, 13, which are mounted on the shaft 14 by means of a key connection. With the inner planes of the beads in which the radial grooves of the triangular profile are made, the coupling halves 12 and 13 are adjacent to the end planes of the disk hub from opposite sides 11. In the hub of the disk 11, axial holes are made in which the spring-loaded balls 15, 16 are located, which are included in the radial grooves of the flanges of the half-couplings 12, 13. The half-couplings 12, 13 together with the spring-loaded balls and 15, 16 form a safety clutch eliminating possible overload of the electric motor.

The shaft 14 structurally integrates the motor shaft and the pump shaft and thus represents a single electric pump shaft with which the pump housing 17 is rigidly connected.

The shaft 14 together with the housing 17 is mounted on bearings 18, 19 located in the bores of the side covers 20, 21 of the pump frame 22, and, in addition, has an additional bearing 23 located in the annular bore of the flange 24 connected to the outer supporting shield 2 of the motor housing .

The shaft 14 of the electric pump is made hollow. Its central axial channel is interfaced with the cavity of the centrifugal wheel 25, rigidly attached to the wall of the housing 17 from the inside, and the opening of the inlet pipe 26 connected to the cover 27 of the outer support shield 2. To supply the pumped fluid to the centrifugal wheel 25 through the central channel of the shaft 14, the inlet pipe 26 equipped with a supply sleeve 28, rigidly connected with it and included in the Central axial channel of the shaft 14. The sleeve 28 is separated from the inner surface of the shaft 14 by a seal 29, filling the annular gap between the sleeve 28 and the shaft.

The pump housing 17 is made prefabricated, which is necessary for installation in its cavity of a stationary outlet 30, on which a scoop 31 is fixed. If necessary, an additional scoop can be installed (shown by dash-dotted lines). The outlet 30 is rigidly fixed to the outer cover 20 of the pump frame 22 by means of a flange 32 to which the outlet pipe 33 is connected. To output the pumped fluid coming from the channel of the scoop 31, the outlet 30 is provided with a central channel coaxial with the hole of the pipe 33 and the channel of the pump shaft 14.

To cool the fuel elements in the motor design, a combined self-cooling system is provided, including structural elements in the form of blades 34, 35 at the ends of the flanges of the coupling halves 12 and 13, and blades 36 on the outer surface of the central disk 11 of the rotor, as well as a fan wheel 37 mounted on the end section shaft 14 in the cavity between the supporting shield 2 of the motor housing and the cover 27 connected to it, provided with ventilation holes, and a network of ventilation channels formed outside perishable motor housing through the housing 38, the female housing rib.

To protect the central annular cavity of the electric motor from the penetration of the pumped liquid, a combined sealing system is provided. On the inner side cover 21 of the pump bed 20, labyrinth and groove seals filled with grease are made. Groove seals are also provided between the shaft 14 and the flange 39, which holds the bearing 19 from axial displacement, between the shaft 14 and the surfaces of the supporting shield 2 of the motor housing, the flange 24, the inlet pipe 26 covering it. In addition, to increase the reliability of the seal in the end bore of the shield 2 adjacent to the edge of the flange 24, the sleeve 40 is installed on the shaft 14.

Scoop electric pump works as follows. Before starting the electric pump, the pump is filled with the pumped liquid in accordance with the established rules for scoop pumps.

After performing the steps related to priming the pump, its electric motor is turned on, connecting the stator winding to the network. As a result of the action of a rotating magnetic field on the conductors of the short-circuited windings of the magnetic circuits 9 and 10, the rotor of the electric motor and the shaft 14 of the electric pump together with the pump housing 17 are rotated.

Movable fluid through the Central channel of the shaft 14 enters the centrifugal wheel 25, where, under the action of centrifugal forces, it is discarded from the central zone of the cavity of the housing 17 to its periphery, where excessive pressure is created. The movement of the liquid from the center and the creation of excess pressure in the outer zone of the cavity of the housing 17 is facilitated by the internal ribs made on its walls. In the area of increased liquid pressure, there is an inlet opening of the scoop 31, through which the liquid flow enters the channel of the scoop, and then into the central channel of the outlet 30, from where the transported liquid is diverted to the intended purpose through the opening of the outlet pipe 33 and an attached pipe (not shown).

In the event of a moment of resistance forces exceeding the permissible value on the electric pump shaft, for example, due to the failure of the bearings, the safety clutch activates: the spring-loaded balls 15 and 16 are pressed into the holes of the hub of the central disk 11 of the rotor in which they are located. As a result of this, the disk 11 is slipping relative to the coupling halves 12, 13, which serves as a signal to disconnect the electric motor from the network.

The cooling system of the fuel elements of the electric motor is self-ventilation. When the shaft 14 of the electric pump rotates, the air masses located inside the central annular cavity of the motor housing, the blades 34, 35, 36 of the coupling halves 12, 13 and the disk 11 are set in motion, which helps to equalize the temperature inside the cavity, and heat is removed to the outside by convection through the cooled outside, a finned electric motor casing, which is subjected to forced external blowing by means of a fan wheel 37, mounted on the end portion of the shaft 14 in the cavity between the supporting shield 2 and the cover 27. Cooling supplying gas (air) to the wheel 37 enters through openings 41 in the cover 27 and is guided by the blades of the wheel 37 through the radial channels in the rim of the cover 27 and the annular protrusion of the shield 2 into the longitudinal channels 42 of the motor housing, which are formed between the edges of the housing through the casing 38, covering body ribs outside.

The proposed design of the scoop electric pump is compact, technologically advanced to manufacture, small-sized, has improved operational and technical indicators, and is convenient in commissioning and maintenance.

Claims (5)

1. A scoop electric pump combining an asynchronous electric motor in a single unit, comprising a motor housing, a rotor, a rotor shaft, shaft bearings, stator and rotor magnetic circuits, a safety clutch and a self-cooling system, and a scoop pump including a bed, bed frame side covers, a pump shaft, an assembly a hollow body ribbed from the inside, rigidly connected to the pump shaft, shaft bearings, a centrifugal wheel, rigidly fixed to the inside of the housing, a ladle installed in the housing cavity on a fixed outlet, input and output nozzles, characterized in that the asynchronous electric motor has an end shape, the motor housing is rigidly attached to the cover of the pump frame and consists of two support plates rigidly connected to each other, forming a central annular cavity, inside of which, on each support panel, one is fixed by means of fixing supports annular stator magnetic circuit with m-phase field winding, separated by air gaps from rotor magnetic circuits with short-circuited windings, located in the cavity between stator magnetic circuits, and the rotor of the electric motor is prefabricated and includes a central disk on which one ring rotor magnetic circuit is fixed on both sides, and a safety clutch consisting of two half-couplings rigidly mounted on the rotor shaft, on the cylindrical surfaces of which the central mounting hole is freely mounted a disk, and devices for interfacing a central disk with half-couplings, each of which contains two spring-loaded balls placed in the axial hole of the disk hub and in leading into the radial grooves of a triangular profile, made in the annular flanges of the coupling halves adjacent to the disk from opposite sides. 2. The electric pump according to claim 1, characterized in that the rotor shaft of the electric motor and the pump shaft are structurally combined and form a single electric pump shaft, and its thrust bearings are placed in the bores of the side covers of the pump frame, and an additional bearing is installed on the shaft end portion from the motor side, located in the end bore of the flange attached to the outer supporting shield of the motor housing. 3. The electric pump according to claim 1 or 2, characterized in that the shaft of the electric pump is hollow, and its central axial channel is interfaced with the cavity of the centrifugal pump wheel and the inlet of the inlet pipe, the inlet pipe mounted on the cover of the outer support shield of the motor housing and is rigidly equipped with a connected supply sleeve that is included in the central axial channel of the electric pump shaft and is separated from the shaft surface by a seal placed in the annular gap between the shaft and the sleeve. 4. The electric pump according to claim 1, characterized in that the self-cooling system of the electric motor is combined and includes structural elements in the form of blades made on the ends of the flanges of the coupling halves of the safety clutch and on the outer surface of the central rotor disk, a fan wheel mounted on the end of the electric pump shaft and placed in the cavity between the outer supporting shield of the motor housing and the lid attached to it with an inlet pipe provided with ventilation holes, and a network of ventilation catch formed externally finned motor housing through the housing, the housing enclosing rib. 5. The electric pump according to claim 1, characterized in that the central annular cavity of the motor housing is protected from penetration of the pumped liquid from the side of the inner side cover of the pump frame by a labyrinth-groove seal of the pump shaft, made in the cover and flange attached to the cover and holding the shaft bearing from axial displacement, and on the inlet pipe side, by a combined shaft seal, represented by grooves in the outer supporting shield of the motor housing and the rib of the flange attached to Itu, in the front bore of which is placed an additional shaft bearing of the electric pump in combination with a cuff mounted on the shaft and placed in the bore of the shield from the side of the flange rib.

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