RU81010U1 - SHORT-CLOSED ROTOR - Google Patents

Abstract

The utility model relates to electrical engineering, namely, to the features of the design of squirrel cage rotors for electric machines.

The objective of the utility model is to create a rotor of electric machines, the frontal part of the short-circuited winding - the squirrel cage of which is connected over the entire range of frequencies of rotation of the machine with the rotor body in such a way that no natural oscillations occur or only differential natural oscillations arise.

To solve the problem in a squirrel-cage rotor, the clamping rings holding the iron package in a compressed state are made in such a way that between their outer diameter and the frontal parts of the squirrel cage a minimum possible clearance of (0-0.15) mm is ensured, the short-circuit rings have axial grooves that serve to install these rings on the squirrel cage rods. Short-circuited rings are soldered to the squirrel cage rods so that the rods protrude beyond the rings. Short-circuiting rings are machined coaxially with the shaft along the inner and end surfaces.

The gap between the pressure rings and the frontal parts of the squirrel cage rods provides free movement of the rods relative to the pressure rings with a thermal change in geometric dimensions, also, due to the very small size of the gap, the pressure rings prevent the radial displacement of short-circuited rings, due to unilateral centrifugal forces arising due to residual uncontrolled unbalance of these rings. The mechanical treatment of the inner and end surfaces of short-circuiting rings reduces the centrifugal forces described above. The part of the squirrel cage rods that extends beyond the short-circuit rings acts as a centrifugal fan.

Fig. 3

Description

The utility model relates to electrical engineering and can be used in the manufacture of squirrel-cage electric motors.

Known squirrel cage rotor with a winding made by injection molding. In this design, short-circuiting rings are located close to the iron package and simultaneously serve as clamping rings. Centrifugal fan blades are made on the end surface of the short-circuiting rings, and the outer and inner surfaces are machined, which allows to reduce the imbalance of short-circuiting rings (See. VL80 Electric Locomotive Operation Manual, Moscow, 1982, Transport, p. 44).

The disadvantage of such a rotor is: the lack of a gap between the short-circuit ring and the iron package, which prevents thermal changes in the geometric dimensions of the squirrel cage rods, which can lead to the breakage of the rods and the relatively high residual unbalance of the short-circuit rings, caused by uneven casting.

A squirrel-cage rotor is known, the winding of which is made by soldering (welding) short-circuited rings with squirrel cage rods installed in grooves of an iron package held in compression by pressure rings located under the squirrel cage rods. In this design, it is possible to install short-circuiting rings at a distance from the iron package, sufficient to prevent the occurrence of harmful effects from thermal resizing of the short-circuited winding on the squirrel cage rods (See. “Traction

electric motors of electric locomotives, Novocherkassk, 1998, Nautilus Agency, p. 184 ”).

The disadvantage of this squirrel-cage rotor is that in rapidly rotating asynchronous motors, the frontal parts of the rotor winding protruding from both sides of the iron stack are very hot and, due to large centrifugal forces, are at risk of destruction due to uncontrolled imbalances. In addition, any squirrel cage construction drawn from the rods has vibration in the radial direction in the area of the frontal part of the winding, which can lead to destruction of the squirrel cage design.

To control centrifugal forces in the zone of short-circuited rings of an asynchronous machine, shrink rings worn on short-circuited rings have been used for many years. Shrink rings only serve as mechanical protection against bending. The whole structure remains vibrating.

The closest in technical essence is a squirrel-cage rotor known from RF patent No. 02168832, in which this problem is solved by using a support ring mounted on the shaft, to the outer surface of which a short-circuit ring is adjacent directly or on separate segments through an elastic element and shrinked to it a ring spanning a short ring.

This design has good damping properties with respect to forced and resonant vibrations, however, due to the tight contact of the short-circuited ring with the support ring, forces are created that can destroy the short-circuited winding, due to various thermal changes in the geometric dimensions of the materials of the short-circuited rotor winding and the supporting ring.

The objective of the utility model is to increase reliability by eliminating resonant oscillations caused by residual

uncontrolled unbalance of short-circuited rings and harmful effects on the squirrel cage rods due to various thermal changes in the geometric dimensions of the materials of the short-circuited rotor winding and the support ring.

This problem is solved in that a squirrel-cage rotor for an asynchronous machine, comprising a packet of iron fixed to the shaft and held on both sides by pressure rings, in the grooves of which are rods of a squirrel cage, each of which is connected to short-circuit rings outside the packet of iron, while the packet of iron held in compression by clamping rings made with the following differences: the outer diameter of the clamping rings is selected so that between these rings and squirrel cage rods is about espechen gap δ = (0-0,15) mm, which prevents the occurrence of counteracting thermal expansion in the axial direction of the short-circuited winding and the pressure rings function performed limiter radial displacements of short-circuiting rings, when subjected to unilateral centrifugal forces caused by the residual unbalance short-circuiting rings. Axial grooves are made in the short-circuited rings to accommodate the squirrel cage rods, the connection of which with the short-circuited rings is made by soldering along the contour of the rod over the entire width of the short-circuited rings. Short-circuited rings are protected from centrifugal forces by shrink rings having an annular protrusion on the inner surface that fixes the shrink ring in the axial direction on the short-circuited ring, which has an annular groove on the outer surface made (0.5-1.0) mm wider than the shrink protrusion rings, which facilitates assembly without adversely affecting structural strength. The proposed rotor design due to the location of the support of the short-circuited winding under the rods (rather than short-circuited rings) allows

machining the inner and end surfaces of short-circuiting rings coaxially with the rotor shaft, which significantly reduces the residual uncontrolled imbalance of short-circuiting rings. The squirrel cage rods, outside the short-circuiting rings, act as a centrifugal fan.

The utility model is illustrated by drawings, which depict:

figure 1 is a longitudinal section of the end part of the squirrel-cage rotor with a clamping ring made in the form of a hub and rim connected by radial ribs;

figure 2 is a cross section of a short-circuiting ring, explaining the execution of the soldering rods of squirrel cage;

figure 3 is a longitudinal section of the end part of the squirrel-cage rotor with a clamping ring in the form of a washer.

The squirrel-cage rotor shown in Fig. 1 consists of a packet of iron 1, in the grooves of which are located and fixed from axial movements by core in its middle part, squirrel cage rods 2, short-circuiting rings 3 with longitudinal through grooves connected to the squirrel cage rods 2 by soldering and protected from the action of centrifugal forces by shrink rings 4 and clamping rings 5, holding the package of iron 1 in a compressed state. The outer surface of the clamping ring 5 is mechanically processed so that a gap of δ = (0-0.15) mm to the squirrel cage rods 2 is provided. The clamping rings 5 are located under the short-circuited winding rods, and not under the short-circuited rings 3. Short-circuited rings 3 after soldering to the squirrel cage rods 2 are machined along the inner and end surfaces coaxially with the rotor shaft, which can significantly reduce one-sided centrifugal forces resulting from residual uncontrolled unbalance of short-circuiting rings 3. The implementation of the clamping rings 5 in the form of a hub and rim,

connected by radial ribs, minimize the resistance to cooling air passing through the channels 6.

The positive effect of the proposed utility model is manifested in the following: a squirrel-cage rotor is very hot during operation. Copper rods 2 of a squirrel cage, having a thermal expansion coefficient higher than the thermal expansion coefficient of steel and increase in size when heated, which leads to a displacement of their frontal parts relative to the pressure rings 5 in the axial direction. The gap δ = (0-0.15) mm, provided between the clamping ring 5 and the rods 2 of the squirrel cage provides free axial movement of the latter. At high rotor speeds, the clamping rings, due to the small gap to the squirrel cage rods 2, act as a limiter of the radial displacements of short-circuiting rings caused by a one-sided centrifugal force that can lead to the destruction of the squirrel cage rods 2. The resulting force is caused by the inevitable residual imbalance of the short-circuited rings 3. When the short-circuited rings 3 are deflected by an amount greater than the provided gap between the pressure rings 5 and the squirrel cage rods 2, the rods from the side opposite to the bias direction are lowered onto the pressure rings 5, which prevent further displacement of the short-circuited rings 3. Due to the very small size of the gap 8 between the clamping rings 5 and the rods 2 there are no displacements of short-circuiting rings 3, which can lead to destruction of the squirrel cage.

Soldering a short-circuiting ring 3 with squirrel cage rods 2, according to FIG. 2, is performed over the entire width of the short-circuiting ring 3 along the surface of the rod 2 adjacent to the ring. The contact area with this design increases several times, which increases the reliability of the connection and reduces heat in place connections.

Figure 3 presents an embodiment with clamping rings in the form of washers. The support for the rods 2 is the axially developed part 7 of the clamping washer 5. The design of the clamping rings in the form of washers allows axial grooves to be made in them to accommodate the squirrel cage rods 2 in them. Such a design of the clamping rings makes it possible to keep in compression not only the yoke of the rotor iron packet, but also the tooth zone, which reduces core fluffing and eliminates the possibility of breaking the teeth of the outermost sheets of the rotor iron packet. For the passage of cooling air through the ventilation channels 6 in the clamping washer 5, holes 8 are provided that are aligned with the channels 6.

Claims (1)

A squirrel-cage rotor for an asynchronous machine, comprising an iron pack fixed to the shaft and held in compression by the pressure rings, in the grooves of which are squirrel cage rods, each of which is connected outside the iron package to short-circuited rings held in the radial direction by shrink and pressure rings performing support function for a short-circuited winding, characterized in that the clamping rings are installed with a gap of δ = (0-0.15) mm from the squirrel cage rods, and short-circuiting ca machined on the inner surface coaxially with the rotor shaft.