EA016647B1 - Heat exchanger of an inverted electrical machine - Google Patents

Abstract

An inverted electrical machine comprising a body with end shields adjoining to it, a rotor, which can be mounted on bearings set in the end shields, is disclosed. The machine comprises at least one air heat exchanger disposed inside of the machine body on an external side of the rotor, the heat exchanger includes heat-transfer elements, and a stator set inside of the rotor and mounted on one of the end shields as well. The electrical machine according to the present invention is characterized in that the heat-transfer elements of the air heat exchanger are arc-shaped.

Description

FIELD OF THE INVENTION

The present invention relates to electrical engineering, namely to reversed-type multiphase electric machines.

State of the art

The prior art electric multiphase machines (V.V. Dombrovsky, G.M. Khutoretsky, Fundamentals of Designing Electric AC Machines. L .: Energy, 1974), which contain a housing with end shields adjacent to it. Also inside the housing are a heat exchanger, stator, rotor and bearings. The heat exchanger consists of heat transfer tubular elements with fins. The stator is installed on the inner surface of the housing and contains a magnetic circuit with coils and coil coolers laid in its grooves. The bearings are located in the end shields. The rotor contains a magnetic circuit, a fan and a shaft supported by bearings.

When an electric machine is operating in it, both as a whole and in its nodes, forced oscillations arise, caused by alternating electromagnetic processes and mechanical factors caused by the rotation of the rotor. The spectrum of these oscillations is often large and especially increases in multiphase controlled machines and can be in the frequency range from 10 to 1000 Hz or more. Therefore, ensuring the detuning of the eigenfrequencies of the numerous elements of the machine from the values of the perturbing frequencies is quite difficult and it is not always possible to ensure that the values of the eigenfrequencies of the elements are sufficiently far from the values of the perturbing frequencies so as not to cause increased vibration amplitudes (close to resonant vibration amplitudes). Fluctuations create alternating mechanical stresses in the elements, which, in turn, should be no more than the required level to provide the necessary resource of the elements (fatigue strength) during the specified period of operation of the machine. The presence of a wide range of disturbing frequencies leads to the fact that a number of elements (parts or assemblies), especially flat (with a small thickness) and extended elements, have a limited service life due to the relatively high variable component of mechanical stresses and, accordingly, low fatigue strength and require replacing them during major repairs or even more often. In particular, these are the fastening elements of the frontal sections of the windings, the elements of heat exchangers, thrust ball bearings, etc. This reduces the reliability of the machine and increases the cost of operating costs. The solution of these shortcomings by using more massive elements, in which the initial values of the natural frequencies will be several times higher than the values of the disturbing frequencies, leads to an increase in the partial dimensions of the nodes, an increase in the mass of the machine and, accordingly, an increase in the cost of the machine.

In patent EA 012865, selected as a prototype, another construction of an electric machine is described. The specified reversed type machine comprises a housing with end shields adjacent to it, on which bearings are mounted; a rotor with a fan installed in it; an air heat exchanger located inside the machine body on the outside of the rotor. The heat exchanger contains heat transfer elements (TE) with external fins, mounted on water combining collectors, which, in turn, are mounted on the inner surface of the machine body. The stator is installed inside the rotor, attached to one of the end shields and contains a clearly pole magnetic circuit with coils.

To ensure effective cooling of the air inside the machine, fuel cells are located along the longitudinal axis of the machine and have an appropriate length. And the greater the power of the machine, the greater the length of the machine and, accordingly, the length of the fuel cell.

The large length of the FC leads to a decrease in the spectrum of the natural frequencies of the FC, which increases the amplitude of the forced vibrations of the FC, the amplitude of the alternating mechanical stresses and, accordingly, reduces the life of the heat exchanger, the reliability of the machine as a whole. The use of heat exchangers with shorter FCs and, accordingly, with a higher amplitude spectrum of natural frequencies will lead to a decrease in the amplitude of alternating mechanical stresses. But then it will be necessary to install several of these heat exchangers in order to maintain the overall design length of the heat exchanger. This leads to an increase in the number of water collectors, the length of welds, increases the number of connecting elements between the elements and complicates the system of hydraulic connections of water paths, which in general leads to a more complicated design of the heat exchanger, lower reliability of the machine, increased operating costs and cost of the machine.

SUMMARY OF THE INVENTION

The objectives of the present invention are to increase the strength characteristics of the heat exchanger while maintaining or increasing the length of its elements, simplifying the design of the heat exchanger and increasing its service life, increasing the reliability of the machine as a whole, reducing operating costs and the cost of the machine.

The objectives of the invention are solved using an electric machine of the reversed type, comprising a housing with adjacent end shields, a rotor, which can be mounted on bearings located in the end shields. The machine also contains at least one air heat exchanger located inside the machine body on the outside of the rotor and containing heat transfer elements, as well as a stator mounted inside the rotor and attached to one of

- 1 016647 end shields. In the present embodiment, the longitudinal direction of the heat transfer elements is preferably substantially parallel to the axis of rotation of the rotor or, in another formulation, the heat transfer elements essentially lie in planes to which the axis of rotation of the rotor belongs; at the same time, other orientations and orientations of the heat transfer elements may be provided. The electric machine according to the present invention is characterized in that the heat transfer elements of the air heat exchanger are in the form of arcs.

In a preferred embodiment, the heat transfer elements are provided with elastic elements, wherein the heat transfer elements in the housing and the elastic elements on the heat transfer elements are arranged so that the convex sides of the heat transfer elements face the inner surface of the engine housing, and the elastic elements rest on the inner surface of the housing, while there are gaps between heat transfer elements and the inner surface of the housing. Moreover, in a preferred embodiment, the heat transfer elements in the housing and the elastic elements on the heat transfer elements are arranged so that the elastic elements are in a compressed state, which provides an additional improvement in the properties of the heat exchanger and the electric machine as a whole.

The heat transfer elements may have external ribs, and the elastic elements may be located on the heat transfer elements between the ribs. In another embodiment, the heat transfer elements may have at least one area without ribs, and the elastic elements may be located on the heat transfer elements in these areas without ribs.

The elastic elements are preferably made in the form of annular sleeves of elastic material. Further improvement in the properties of the present invention can be achieved if the elastic elements have non-linear stiffness.

In an advantageous embodiment of the present invention, the air heat exchanger comprises at least one water collector to which heat transfer elements are connected. The air circulation in the machine body is preferably provided by the rotation of the rotor, and in order to increase the heat transfer efficiency in the rotor or on the rotor, a fan can be installed. In a preferred embodiment of the present invention, the stator contains a clearly pole magnetic circuit with coils.

The technical result of the present invention is to increase the strength characteristics of the heat exchanger while maintaining or increasing the length of its elements by changing the shape of the elements and the implementation of their prestress. In addition, an improved damping of the movements of the heat exchanger elements is also provided, which also leads to a simplification of the heat exchanger design and an increase in its service life, an increase in the reliability of the machine as a whole and lower operating costs and the cost of the machine.

List of figures

In FIG. 1 is a schematic longitudinal sectional view of an exemplary embodiment of a reversed type electric machine of the present invention.

In FIG. 2 is a schematic cross-sectional view of an exemplary embodiment of a reversed type electric machine of the present invention.

In FIG. 3 schematically depicts an air heat exchanger in the longitudinal direction of an exemplary embodiment of a reversed type electric machine of the present invention (top view).

Information confirming the possibility of carrying out the invention

The following describes one of the possible embodiments of the electric machine of the present invention. The reversed type electric machine (see Figs. 1, 2) has a housing 1, on the ends of which end shields are installed 2. Sliding bearings 3 and 4 are installed in the end shields 2. The rotor 5 is installed inside the housing 1, on which the air blades 6 and magnetic system 7.

A disk 9 is attached to the power ring 8, which, in turn, is seated on the shaft 10. The shaft 10, on the one hand, passes through the bore of the stator 11 and rests with its ends on the bearing assemblies 3 and 4. The stator 11 is installed inside the rotor 5 and attached to one from end shields 2.

The stator 11 has a magnetic core 12 and an excitation winding in the form of coils 13 laid in the grooves of the magnetic core 12.

The air heat exchanger 14 (see also Fig. 3) is located outside the power ring 8 concentrically with respect to it and is mounted on the housing 1. The air heat exchanger 14 consists of heat transfer elements 15 with fins 16 closed at the ends by water collectors 17. Heat transfer elements 15 are located mainly in the longitudinal direction with respect to the machine. The heat transfer elements 15 have sections without ribs 18 on which elastic elements 19 are mounted, for example, made in the form of ring bushings. The elastic elements 19 are made of an elastic material with a non-linear characteristic of mechanical stiffness. The air heat exchanger 14 is placed and secured with fastening units 20 on the inner surface of the housing 1. Moreover, the configuration of the air heat exchanger 14 is made so that when fixing the heat exchanger 14 on the housing 1, the elastic elements 19 are compressed and there is no contact with the heat transfer

- 2 016647 elements 15 of the housing 1.

The positive effect of the execution of the heat transfer elements 15 in the form of arcs, the installation of elastic elements 19 and compression of the elastic elements is as follows. To increase the service life of the heat transfer elements 15 and the air heat exchanger 14 as a whole, it is advisable that the heat transfer element 15 has a first and subsequent natural frequencies greater than 1000-1200 Hz or more. With an increase in the eigenfrequencies, the amplitude of the forced oscillations and the level of alternating mechanical stresses decrease significantly. This allows you to increase the number of oscillation cycles of the TE 15, which accordingly leads to an increase in the duration (resource) of the operation of the TE 15 and increase the reliability of the machine as a whole. Therefore, to increase the level of natural frequencies of TE 15, it is performed in the form of an arc, since the arc section has a level of natural frequencies higher than the same rectilinear section, due to the increase in stiffness due to the presence of additional ring stiffness. Also, the level of natural frequencies increases due to the formation of mechanical compression stress of the TE 15 in the longitudinal direction due to the formation of the transverse force acting on the TE 15 due to the compression of the elastic element. That is, a prestressed structure was created in which the level of natural frequencies is higher than that of mechanically unstressed structures. The introduction of an intermediate support on the TE 15 makes it possible to reduce the span length of the TE 15, which also significantly increases the level of the natural frequencies of the element, since the frequency increases in proportion to the cube from a decrease in the span between the supports. And the presence of an elastic support 19 allows you to damp the forced vibrations of the TE 15, reduce the amplitude of the forced vibrations, reduce the value of the alternating mechanical stresses in the TE 15.

Thus, in the proposed design of the reversed-type electric machine due to the obtained positive effects, it is possible to use a more simplified heat exchanger design, especially for high-power machines, to increase the reliability of the machine by increasing the life of the air heat exchanger and the machine as a whole, as well as reducing the cost of operating costs and the machine as a whole by increasing the resource of work.

Claims (7)

CLAIM 1. Electric reversed type machine, comprising a housing with adjoining end shields, a rotor, at least one air heat exchanger located inside the machine housing on the outside of the rotor and containing heat transfer elements, a stator mounted inside the rotor and attached to one of the end shields characterized in that the heat transfer elements of the air heat exchanger are in the form of arcs. 2. The electric machine according to claim 1, characterized in that the heat transfer elements are provided with elastic elements, the heat transfer elements in the housing and the elastic elements on the heat transfer elements are located so that the convex sides of the heat transfer elements are facing the inner surface of the engine housing, and the elastic elements are based on the inner surface of the housing, while there are gaps between the heat transfer elements and the inner surface of the housing. 3. The electric machine according to claim 2, characterized in that the heat transfer elements in the housing and the elastic elements on the heat transfer elements are located so that the elastic elements are in a compressed state. 4. The electric machine according to claim 2, characterized in that the heat transfer elements have external ribs, and the elastic elements are located on the heat transfer elements between the ribs. 5. The electric machine according to claim 2, characterized in that the heat transfer elements have external ribs, and the heat transfer elements have at least one section without ribs, and the elastic elements are located on the heat transfer elements in these sections without ribs. 6. The electric machine according to claim 2, characterized in that the elastic elements are made in the form of annular bushings of an elastic material. 7. The electric machine according to claim 2, characterized in that the elastic elements have non-linear stiffness.