RU207295U1 - SUBMERSIBLE ELECTRIC MOTOR - Google Patents

Abstract

The utility model relates to electrical engineering and can be used as a drive for a submersible centrifugal pump for mechanized production of formation fluid from an oil well. The submersible electric motor contains a rotor and a stator, the magnetic circuit of which is recruited from sheets of electrical steel having closed grooves with wires laid in them with insulation in the form of a dielectric sheath, while the grooves are made with the possibility of laying in them a larger number of wires with the same section of the conductive core, but with thinner insulation, the breakdown voltage of which is not less than the breakdown voltage of insulation in the form of a dielectric shell, and the number of insulation layers is equal to the number of insulation layers in the form of a dielectric shell. The technical result consists in improving the manufacturability of manufacturing and increasing the rated power of the electric motor, increasing the degree of unification of the manufacture of submersible electric motors, as well as in the implementation of the specified purpose (expansion of the arsenal of technical means for the specified purpose). 2 ill.

Description

The utility model relates to electrical engineering and can be used as a drive for a submersible centrifugal pump for mechanized production of formation fluid from an oil well.

The submersible electric motor, as part of the submersible pumping unit, is one of the main components of the electric centrifugal pump units, with the help of which more than 80% of all oil in the country is produced. A submersible electric motor transmits rotation to a pump filled with formation fluid.

Known electric motor for submersible electric pumps for oil production, containing a stator in the form of a pipe with a pressed-in magnetic circuit, a three-phase winding and placed inside the rotor in the form of packages of sheet electrical steel (RU 2487273 C1, F04D 13/10, H07K 9/193, publ. 10.07. 2013, Bulletin No. 19). However, it has a low degree of standardization in the manufacture of submersible oil-injected electric motors.

Known submersible oil-filled electric motor containing a squirrel-cage rotor and a stator, the magnetic circuit of which is recruited from sheets of electrical steel having closed grooves made in the form of a trapezoid so that the walls of the teeth are parallel to each other (RU 36066 U1, Н02К 1/16, Н02К 5/12, publ. 20.02.2004 Bul. No. 5). The disadvantage of this electric motor is the low rated power associated with a limited number of conductive conductors in the stator groove, as well as a low degree of unification of the manufacture of submersible electric motors.

The specified submersible electric motor, in terms of its technical characteristics and purpose, is the closest to the proposed utility model and is taken as a prototype.

The utility model was given the task of increasing the rated power and increasing the degree of unification of the manufacture of submersible electric motors.

The technical result of the utility model consists in improving the manufacturability of manufacturing and increasing the rated power, increasing the degree of unification of the manufacture of submersible electric motors, as well as in the implementation of the specified purpose (expansion of the arsenal of technical means for the specified purpose).

The common essential features of the prototype and the claimed utility model are a rotor and a stator, the magnetic circuit of which is made up of sheets of electrical steel having closed grooves with wires laid in them with insulation in the form of a dielectric sheath.

The technical result is achieved due to the fact that in a submersible electric motor containing a rotor and a stator, the magnetic circuit of which is recruited from sheets of electrical steel, having closed grooves with wires laid in them with insulation in the form of a dielectric shell, the grooves are made with the possibility of laying more wires in them with the same section of the conductive core, but with thinner insulation, the breakdown voltage of which is not less than the breakdown voltage of insulation in the form of a dielectric shell, and the number of insulation layers is equal to the number of insulation layers in the form of a dielectric shell.

Various versions of electric motors with closed slots are known, including those with slots having a cross-section in the form of an isosceles trapezoid.

To achieve a higher filling factor of the groove with wires with thinner insulation, we will consider two options for the execution of submersible electric motors with the initial laying of wires along the larger or smaller bases of the trapezoid.

We proceed from the fact that when calculating the number of wires with thinner insulation for laying in closed slots of a submersible electric motor, having a cross-section in the form of an isosceles trapezoid, it is necessary, in particular, that at least or more wires with thinner insulation be laid near ( along) the larger base of the trapezoid, or more wires with thinner insulation were laid near the smaller base of the trapezoid.

Obviously, when calculating the number of wires with thinner insulation, located near the larger base of the isosceles trapezoid, required for laying in the stator groove of the electric motor, it is necessary to proceed from the expression

lб≥mв. D max≤nв. D min

where lb. - the length of the larger base of the trapezoid, reduced, in the presence of groove insulation, by its double thickness;

mv. - the number of wires with insulation in the form of a dielectric sheath near the larger base of the trapezoid;

nв. - the number of wires with thinner insulation near the larger base of the trapezoid;

D max - diameter of a wire with insulation in the form of a dielectric sheath;

D min is the diameter of the wire with thinner insulation.

When determining the required number of wires with thinner insulation for laying in a groove near the smaller base of an isosceles trapezoid, it is necessary to proceed from the expression

lm. ≥mn. D max≤nн. D min,

where lm. - the length of the smaller base of the trapezoid, reduced, in the presence of groove insulation, by its double thickness;

mn. - the number of wires with insulation in the form of a dielectric sheath

near the smaller base of the trapezoid;

nн. - the number of wires with thinner insulation near the smaller base of the trapezoid;

D max - diameter of a wire with insulation in the form of a dielectric sheath;

D min - diameter of a wire with thinner insulation.

A smaller base of a trapezoid means a base of a trapezoid with a shorter length compared to the length of the other base, and a large base of a trapezoid means a base with a greater length compared to the length of the other base.

The presence of slot insulation reduces the cross-sectional area of the slot intended for laying the wires of the phase winding. Therefore, when calculating the number of wires with thinner insulation for laying along a larger or smaller base of the trapezium, the presence of groove insulation on both sides of the groove is taken into account, and the length of the base of the trapezium is reduced by twice the thickness of the groove insulation.

Obviously, in the absence of groove insulation of length greater than 16. and less than 1 m, the bases of the trapezoid are not corrected when determining the number of wires per double thickness of groove insulation.

FIG. 1 conventionally depicts a submersible electric motor, general view; in fig. 2 - section A-A in Fig. 1.

The submersible electric motor 1 contains a stator 2, assembled from sheets of stator 3 with trapezoidal closed slots 4, in which wires 5, rotor 6 are located.

The submersible motor works as follows.

After connecting the electric motor as part of a submersible pumping unit (not shown) to the alternating current network, the rotating magnetic flux, which is directly proportional to the number of turns of the phase winding of the stator 2, containing wires 5, provides the torque required to extract the formation fluid from the well on the shaft of the pumping unit.

Prototypes of submersible electric motors were made, in which, due to the use of wires with thinner insulation instead of the PPI-U wire, the number of wires 5 in slot 4 was increased from 10 to 12.

An increase in the number of wires in the groove due to the replacement of the PPI-U wire with a wire with thinner insulation and the same breakdown voltage, practically without any additional changes, led to an increase in the rated motor power by 25%, from 36 to 45 kW. The use of wires with thinner insulation laid in the stator groove using the same parts and materials for the assembly of the electric motor achieves not only an increase in the rated power, but also an increase in the degree of unification of the manufacture of submersible electric motors and, accordingly, an expansion of the arsenal of technical means for this purpose.

Thus, the claimed utility model provides a technical result that objectively manifests itself both in the manufacture and in the use of the utility model.

The features of the set of essential features of the utility model are interconnected, are in a causal relationship with the technical result, are necessary and sufficient to achieve it.

The proposed technical solution is novel and industrially applicable.

Claims (15)

1. A submersible electric motor containing a rotor and a stator, the magnetic core of which is recruited from sheets of electrical steel having closed grooves with wires laid in them with insulation in the form of a dielectric shell, characterized in that the grooves are made with the possibility of storing more wires in them with the same cross-section of a conductive core, but with a thinner insulation, the breakdown voltage of which is not less than the breakdown voltage of insulation in the form of a dielectric shell, and the number of insulation layers is equal to the number of insulation layers in the form of a dielectric shell. 2. The submersible electric motor according to claim 1, characterized in that the groove is made with a cross-section in the form of an isosceles trapezoid, while, 1b.≥mv. D max≤nв, D min, where lb. - the length of the larger base of the trapezoid, reduced, in the presence of groove insulation, by its double thickness; mv. - the number of wires with insulation in the form of a dielectric sheath near the larger base of the trapezoid; nв. - the number of wires with thinner insulation near the larger base of the trapezoid; D max - diameter of a wire with insulation in the form of a dielectric sheath; D min - diameter of a wire with thinner insulation. 3. Submersible electric motor according to claim 1, characterized in that the groove is made with a cross-section in the form of an isosceles trapezoid, while, lm. ≥mn. D max≤nн. D min, where lm. - the length of the smaller base of the trapezoid, reduced, in the presence of groove insulation, by its double thickness; mn. - the number of wires with insulation in the form of a dielectric sheath near the smaller base of the trapezoid; nн. - the number of wires with thinner insulation near the smaller base of the trapezoid; D max - diameter of a wire with insulation in the form of a dielectric sheath; D min - diameter of a wire with thinner insulation.

Images