EA034958B1 - Axial multiphase non-contact two-input electric machine-generator - Google Patents

Abstract

The invention relates to electrical equipment, particularly to electromechanical energy converters, and can be, for example, used as a converter of mechanical rotation energy into electrical AC energy. The axial multiphase non-contact two-way electrical generator body contains an additional voltage regulator comprising a voltage corrector and a second multiphase full-wave rectifier installed inside the axial yoke of the exciter inductor, correcting and compounding windings, which makes it possible to stabilize the output voltage and to improve weight and size parameters.

Description

The invention relates to electrical engineering, in particular to electromechanical energy converters, and can be used, for example, as a converter of mechanical rotation energy, into alternating current electrical energy.

Known axial two-input non-contact electric machine-generator (RF patent No. 2450411, authors Gait B.Kh., Kashin Ya.M. and others) containing a housing, exciter, pathogen and main generator mounted on one shaft, while the exciter consists of a permanent multipolar magnet of the exciter exciter and a magnetic circuit with a winding of the exciter armature, the pathogen consists of a magnetic circuit with an excitation winding of the pathogen and a magnetic circuit with a winding of the exciter arm, the main generator consists of a magnetic circuit with an excitation winding of the main generator and a magnetic circuit with an armature winding of the main generator. The permanent multipolar magnet of the exciter exciter and the magnetic cores in the grooves of which are placed the windings of the exciter, exciter and the main generator are made axial, while the lateral axial magnetic circuits are rigidly installed in the housing, and the permanent multipolar magnet of the exciter exciter and the internal axial magnetic circuit are rigidly mounted on the shaft with rotation relative to the lateral axial magnetic circuits, while the permanent multipolar magnet of the exciter exciter is installed from the end of one side axial magnetic circuit, and the internal axial magnetic circuit is installed between the lateral axial magnetic circuits, the internal axial magnetic circuit and the lateral axial magnetic circuit, from the end of which there is a permanent multipolar magnet of the exciter exciter, are made two active end surfaces with grooves, and the other lateral axial magnetic circuit is made with one active end surface with grooves, when In the grooves of the lateral axial magnetic circuit with two active end surfaces, a multiphase winding of the exciter armature is laid on the side of the permanent multi-pole magnet of the exciter, and a single-phase excitation winding of the exciter is laid on the opposite side, which is connected to the armature winding of the exciter through a multiphase excitation and a half excitation double excitation connected to a direct current source, in the grooves of the internal axial magnetic circuit from the side of the exciter winding and the additional excitation winding of the exciter, a multiphase winding of the exciter armature is laid, and on the opposite side the single-phase excitation winding of the main generator is laid, which is connected to the exciter armature winding through a multiphase half-wave rectifier In this, a multiphase winding of the armature of the main generator is laid in the grooves of the lateral axial magnetic circuit with one active end surface.

However, the disadvantage of the known two-input electric generator machine is the design complexity due to the fact that its rotor, which is a permanent multipolar magnet of the exciter exciter and an internal magnetic circuit, in the grooves of which are laid a multiphase winding of the exciter armature and a single-phase excitation winding, the main generator, rigidly fixed to one the shaft, contains two parts - an axial permanent multipolar magnet of the exciter exciter and an internal axial magnetic circuit, between which is one of the lateral axial magnetic circuits, fixed in the housing (stator). This complicates the manufacturing technology and assembly of the electrical machine, maintenance and repair, and also reduces the reliability and rigidity of the design of the electrical machine as a whole. In addition, the known electric machine has low overall dimensions due to the large axial dimensions of the electric machine, the irrational use of free space inside the axial magnetic circuits of the pathogen and the main generator. The large dimensions of the known electric machine with its small mass are also due to the fact that the axial permanent multipolar magnet of the exciter exciter and axial magnetic circuits, in the slots of which the windings of the exciter and exciter are laid, have the same dimensions as the axial magnetic circuits of the main generator, while the exciter power and the pathogen is significantly lower than the power of the main generator.

In addition, the known two-input electric generator machine is characterized by low stability of the output voltage with a sharp change in the torque on the shaft (for example, with gusts of wind), due to the fact that the output voltage is a function of the rotor speed, which, in turn, is a function torque on the shaft. Due to the fact that the wind speed is probabilistic in nature, the rotor speed with a change in wind speed is subject to sharp changes.

Of the known technical solutions, the closest to the claimed invention in technical essence and adopted by the authors for the prototype is an axial multiphase two-input contactless electric machine-generator (RF patent No. 2623214, authors Kashin Ya.M., Kashin A.Ya., Knyazev A.S. ) containing a housing, exciter, exciter and main generator mounted on the same shaft mounted in the generator housing in bearing shields, wherein the exciter consists of an axial permanent multipolar magnet of the exciter exciter and an axial magnetic circuit with a multiphase winding of the exciter armature, the exciter consists of an axial magnetic circuit , in the grooves of which a single-phase excitation winding of the pathogen is connected, connected to the winding of the exciter armature through a multiphase half-wave rectifier, and an additional winding of the exciter

- 1 034958 exciter excitation connected to a direct current source, and an axial magnetic circuit with a multiphase winding of the exciter arm, the main generator consists of an axial magnetic circuit of the inductor of the main oscillator, in the slots of which a single-phase excitation winding of the main oscillator is connected, connected to the multiphase winding of the exciter arm through a multiphase half-wave a rectifier, and an axial magnetic circuit with a multiphase winding of the armature of the main generator. An axial magnetic circuit with a multiphase winding of the exciter armature, an axial magnetic circuit in the slots of which are placed a single-phase excitation winding of the pathogen and an additional excitation winding of the pathogen, and an axial magnetic circuit with a multiphase winding of the armature of the main generator are rigidly fixed in alignment with each other on the side surface thereof, while their common the axis of symmetry is the axis of symmetry of the shaft, and the axial magnetic circuit, in the grooves of which are placed a single-phase excitation winding of the pathogen and an additional excitation winding of the exciter, is placed inside the axial magnetic circuit with a multiphase winding of the armature of the main generator, and the axial magnetic circuit with a multiphase winding of the armature of the exciter is located inside the axial magnetic circuit, the grooves of which are laid a single-phase excitation winding of the pathogen and an additional excitation winding of the pathogen, while the axial permanent multi-pole magnet of the exciter exciter, axial magneto a gadget with a multiphase winding of the exciter armature and an axial magnetic circuit with a single-phase excitation winding of the main generator are rigidly fixed to the shaft by means of a disk coaxially to each other, while their common axis of symmetry is the axis of symmetry of the shaft, and the axial magnetic circuit with a multiphase winding of the exciter armature is located inside the axial magnetic circuit of the main inductor generator, and the axial permanent multipole magnet of the exciter inductor is located inside the axial magnetic circuit with a multiphase winding of the exciter armature.

However, a drawback of the two-input electric generator machine known from RF patent 2623214 is the design complexity due to the fact that its rotor and stator contain three main parts (the rotor is an axial permanent multi-pole magnet of the exciter exciter, an axial magnetic circuit with a multiphase winding of the exciter armature and the axial magnetic circuit of the main generator inductor with a single-phase excitation winding of the main generator, a stator, an axial magnetic circuit with a multiphase winding of the exciter armature, an axial magnetic circuit, into the slots of which a single-phase excitation winding of the pathogen is connected, connected to the winding of the exciter armature through a multiphase two-half-wave rectifier, and an additional excitation winding anchors of the main generator), however, for low-power generators (for example, low-power wind generators that convert the kinetic energy of the wind, whose speed is la, into electricity) does not require a pathogen that increases the mass and overall dimensions of the electric machine as a whole.

This complicates the manufacturing technology and assembly of the electrical machine, maintenance and repair, and also reduces the reliability and rigidity of the design of the electrical machine as a whole.

In addition, the well-known two-input electric generator machine is characterized by low stability of the output voltage with a sharp change in the torque on the shaft, due to the fact that the output voltage is a function of the rotor speed, which, in turn, is a function of the torque on the shaft. The output voltage U of such an electric generator machine depends on the rotor speed (axial permanent multipolar magnet of the exciter inductor, axial magnetic circuit with a multiphase winding of the exciter armature and axial magnetic circuit of the inductor of the main generator, in the slots of which a single-phase excitation winding of the main generator is laid):

U = CwO, (1) where C is the design coefficient, w is the rotor speed, φ is the magnetic flux of excitation.

Due to the fact that the torque on the rotor shaft can be unstable, the speed of rotation of the rotor when changing torque is subject to changes.

The possible installation of a constant speed drive affects the overall dimensions of the electric machine-generator, and also reduces the reliability of its operation.

In addition, the value of the output voltage can change when the load of the electric machine-generator changes due to the demagnetizing effect of the load current (armature reaction), which is most manifested when the inductive load.

The objective of the proposed invention is to expand the scope of the axial multiphase non-contact electric generator machine by stabilizing its output voltage while improving its overall dimensions.

The technical result of the claimed invention is to reduce the difference between the set and the actual output voltage while increasing the speed of voltage stabilization and improving the quality of electric energy, reducing the diametrical dimensions of the rotor and stator while simplifying the method of manufacturing an electric generator machine.

The technical result is achieved by the fact that in an axial multiphase non-contact two-input electric machine-generator containing a housing, a pathogen and a main generator, the installation

- 2 034958 mounted on one shaft mounted in the generator housing in bearing shields, and the pathogen consists of an axial magnetic circuit of the exciter inductor, in the grooves of which the field excitation winding connected to the direct current source and an axial magnetic circuit with a multiphase winding of the exciter armature are laid, the main generator consists of an axial magnetic circuit of the inductor of the main generator, in the slots of which the excitation winding of the main generator is connected, connected to the multiphase winding of the exciter armature through a multiphase half-wave rectifier, and an axial magnetic circuit with multiphase winding of the armature of the main oscillator, while the axial magnetic circuit of the exciter inductor, in the grooves of which the exciter winding is laid, and the axial magnetic circuit with a multiphase winding of the armature of the main generator is rigidly fixed in the housing on its side surface coaxially to each other, and the axis of symmetry of the shaft is their common axis of symmetry moreover, the axial magnetic circuit of the inductor of the pathogen, in the grooves of which the excitation coil of the pathogen is placed, is placed inside the axial magnetic circuit with a multiphase winding of the armature of the main generator, while the axial magnetic circuit with a multiphase winding of the armature of the pathogen and the axial magnetic circuit of the inductor of the main generator are rigidly fixed to the shaft by means of a disk coaxially with each other moreover, their common axis of symmetry is the axis of symmetry of the shaft, moreover, an axial magnetic circuit with a multiphase winding of the exciter armature is located inside the axial magnetic circuit of the inductor of the main generator, while a voltage stabilizer is additionally installed in the housing, containing a voltage corrector and a second multiphase half-wave rectifier installed in the inner part of the axial magnetic circuit of the inductor of the pathogen, correcting and compounding the windings laid in the grooves of the axial magnetic circuit of the inductor of the pathogen, while the input of the second multiphase a half-wave rectifier is connected to the phases of the multiphase winding of the main generator armature, and the output is connected to the compound winding, the voltage corrector input is connected to the line voltage of any two phases of the multiphase armature of the main generator, and the output is connected to the correcting winding.

The output voltage is stabilized by reducing the difference between the set and the actual output voltage by a voltage stabilizer containing a voltage corrector and a second multiphase half-wave rectifier installed in the inner part of the axial magnetic circuit of the exciter inductor, which corrects and composes the windings.

Connecting the input of the second multiphase half-wave rectifier to the phase beginnings of the multiphase armature of the main generator armature, and the output to the compound winding provides an increase in the speed of voltage regulation, since the rectified load current flows through the compound winding, which is both a disturbance and a control action.

Connecting the input of the voltage corrector to the line voltage of any two phases of the multiphase winding of the armature of the main generator, and the output to the correcting winding eliminates the inaccuracy of adjusting the input voltage of the compound winding. An inaccuracy in the regulation of the output voltage arises due to the fact that a negative feedback signal is not provided for the compound winding by deviating the output voltage of the generator machine from the set one.

Improving the overall dimensions is achieved by reducing the diametrical dimensions of the rotor and stator by reducing the external and internal diameters of the axial magnetic circuits of the pathogen and the main generator due to the absence of the need to install a exciter and use the free space inside the axial magnetic circuits of the pathogen to place a voltage corrector in this space.

Thus, a decrease in the diametrical dimensions of the rotor and stator leads to an improvement in overall dimensions, namely, a decrease in the overall dimensions and mass of the entire electric machine as a whole due to a decrease in metal consumption due to the absence of an axial permanent multipolar magnet of the exciter inductor and an axial magnetic circuit with a multiphase winding in the proposed design pathogen anchors.

A simplification of the method of manufacturing an axial multiphase non-contact two-input electric machine-generator is achieved by simplifying the technology of its assembly. The mechanical connection of two parts of the rotor instead of three (an axial magnetic circuit with an excitation winding of the main generator and an axial magnetic circuit with a multiphase winding of the exciter armature) between each other makes it possible to rigidly fix all the rotor elements on the shaft by means of a disk coaxially to each other outside the housing (stator). Thus assembled outside the casing (stator), the rotor is completely installed in the casing (stator) and fixed in it. This eliminates the need for installing on the rotor (fixing on the shaft of the electric machine) an axial permanent multipolar magnet of the exciter exciter, and inside the housing (stator) - an axial magnetic circuit with a multiphase winding of the exciter exciter.

In FIG. 1 shows a General view in section of the proposed axial multiphase non-contact two-input electric generator machine; in FIG. 2 - its electrical circuit.

Axial multiphase non-contact two-input electric generator machine contains

- 3 034958 housing 1, the exciter and the main generator mounted on one shaft 5, mounted in the generator housing 1 in the bearing shields 6 and 7. The causative agent consists of an axial magnetic circuit 11 of the exciter inductor, in the grooves of which the exciter field coil 18 connected to the source is laid direct current, and axial magnetic circuit 12 with a multiphase winding 13 of the armature of the pathogen. The main generator consists of an axial magnetic circuit 14 of the inductor of the main generator, in the slots of which the excitation coil 15 of the main generator is connected, connected to the multiphase (in Fig. 2 - nine-phase) winding 13 of the exciter armature through the first multiphase (in Fig. 2 - nine-phase) two-half-wave rectifier 3 , and the axial magnetic circuit 16 with a multiphase (in Fig. 2 - nine-phase) winding 17 of the armature of the main generator.

The axial magnetic circuit 11 of the exciter inductor, in the grooves of which the exciter winding 18 is laid, and the axial magnetic circuit 16 with a multiphase winding 17, the armature of the main generator are rigidly fixed in the housing 1 on its side surface and are aligned with each other, and the axis of symmetry of the shaft 5 is their common axis of symmetry, moreover, the axial magnetic circuit 11 of the exciter inductor, in the grooves of which the exciter winding 18 is laid, is placed inside the axial magnetic circuit 16 with a multiphase winding 17 of the armature of the main generator. The axial magnetic circuit with a multiphase winding 13 of the exciter armature and the axial magnetic circuit 14 of the inductor of the main generator are rigidly fixed to the shaft 5 by means of the disk 2 coaxially to each other. Their common axis of symmetry is the axis of symmetry of the shaft 5, and the axial magnetic circuit 12 with a multiphase winding of the exciter armature is located inside the axial magnetic circuit 14 of the inductor of the main generator.

In the housing 1, a voltage stabilizer is installed, containing a voltage corrector 4 and a second multiphase half-wave rectifier 8, installed in the inner part of the axial magnetic circuit 11 of the exciter inductor, correcting 9 and compounding 10 windings, laid in the grooves of the axial magnetic circuit 11 of the exciter inductor. The input of the second multiphase half-wave rectifier 8 is connected to the phases of the multiphase winding 17 of the armature of the main generator, and the output is connected to the compounding winding 10, the input of the voltage corrector 4 is connected to the line voltage of any two phases of the multiphase winding 17 of the armature of the main generator, and the output is connected to the correcting winding 9 .

The multiphase winding 17 of the armature of the main generator is the output winding of the axial multiphase stabilized two-input contactless electric generator machine, to which consumers are connected.

In the proposed axial multiphase non-contact two-input electric machine generator, the space inside the axial magnetic circuit 11 of the excitation of the pathogen is used to accommodate the second multiphase half-wave rectifier 8 and voltage corrector 4, the diametric size of which is smaller than the outer diameter of the exciter established in the prototype. This leads to a decrease in the mass and size of the entire electric machine as a whole, as well as saving materials used for its manufacture in comparison with the known axial electric machine-generator.

Axial multiphase non-contact two-input electric machine-generator operates as follows. The mechanical energy of rotation is supplied to the generator machine from an external source through a shaft 5, mounted in the generator housing 1 in the bearing shields 6 and 7. When the shaft 5 is rotated with an axial magnetic circuit 12 with a multiphase winding 13 of the exciter armature and axially mounted on it through a disk 2 the magnetic circuit 14 with the excitation winding 15 of the main generator, the residual magnetic flux of the axial magnetic circuit 11 of the pathogen inductor interacts with the multiphase winding 13 of the armature of the pathogen laid in the grooves of the axial magnetic circuit 12.

As a result of this interaction, a multiphase EMF system is induced in the multiphase winding 13 of the exciter armature, which is rectified by the first multiphase half-wave rectifier 3 and fed into the excitation winding 15 of the main generator, laid in the grooves of the axial magnetic circuit 14 of the inductor of the main generator. Under the influence of this voltage, direct current flows in the excitation winding 15 of the main generator.

When the excitation winding 15 of the main DC generator flows around it, a magnetic flux arises, which, when the rotor rotates, interacts with the multiphase winding 17 of the armature of the main generator, laid in the slots of the axial magnetic circuit 16 of the armature of the main generator. As a result of this interaction, in the multiphase winding 17 of the armature of the main generator, a multiphase EMF system is induced, which is supplied to the network.

In the voltage corrector 4, connected to the line voltage of any two phases of the multiphase winding 17 of the armature of the main generator, the output voltage of the main generator is measured and compared with a given value. At the initial time, the EMF of the armature, and accordingly the voltage at the output of the main generator and at the output of the corrector 4, creates a current in the correcting winding 9, which enhances the residual magnetic flux of the exciter inductor. The amplification of this magnetic flux leads to a further increase in the EMF induced in the multiphase winding 13 of the exciter armature, and, accordingly, to an increase in the current in the excitation winding 15 of the main generator

- 4 034958 RA, which will lead to an increase in EMF in the multiphase winding 17 of the armature of the main generator, i.e. voltage at the output of the generator machine. Thus, the machine-generator self-excited and starts to work stably. The growth of the EMF with an increase in the excitation current in the correction winding 9 slows down when the magnetic circuit of the main generator is saturated. When the output voltage deviates from the set value, the voltage corrector 4 ensures the flow of the current in magnitude and direction in the correction winding 9.

When an external direct current source (for example, photovoltaic converters that convert the light energy of the sun into direct current electricity) is connected to the excitation coil 18, an electric current flows through it.

In accordance with the principle of superposition of magnetic fields, the current in the exciter winding 18 together with the current flowing through the correcting winding 9 creates the resulting magnetic field excitation flux. When the rotor rotates, this total magnetic flux interacting with the multiphase winding 13 of the exciter armature, laid in the grooves of the axial magnetic circuit 12, induces a multiphase EMF system in it, which is rectified by the first multiphase half-wave rectifier 3 and is fed to the excitation winding 15 of the main generator, laid in the grooves of the axial magnetic circuit 14 of the inductor of the main generator. A current flows through winding 15, which creates a magnetic flux of excitation of the main generator. This magnetic flux induces a multiphase EMF in the multiphase winding 17 of the main generator armature, which is fed into the network, to the input of the voltage corrector 4 and to the input of the second multiphase half-wave rectifier 8.

When the load is connected to the machine-generator through the phases of the multiphase winding 17 of the armature of the main generator, a current flows, which is rectified by the second multiphase half-wave rectifier 8, connected to the phases of the multiphase winding 17 of the armature of the main generator, and flows through the compound winding 10.

The current flowing through the compounding winding 10, in accordance with the principle of superposition of magnetic fields together with the currents flowing along the excitation winding 18 of the pathogen and the correcting winding 9, creates the resulting magnetic field excitation flux. This magnetic flux, interacting with the multiphase winding 13 of the exciter armature, laid in the grooves of the axial magnetic circuit 12, induces an EMF in it, which is rectified by the first multiphase half-wave rectifier 3 and is fed to the excitation winding 15 of the main generator, laid in the grooves of the axial magnetic circuit 14 of the inductor of the main generator. A current flows through the winding 15, which creates a magnetic flux of the excitation of the main generator, corresponding to a given value of the output voltage.

Since the rectified current flowing through the compounding winding 10 is both a disturbance and a control action, this provides an improvement in the quality of electric energy by increasing the speed of regulation of the output voltage and reducing the value of the output voltage jump at the initial time when the load is connected.

The presence of compounding winding 10 improves the overall dimensions of the entire electric machine due to the fact that part of the excitation power is taken from the multiphase winding 17 of the armature of the main generator. This eliminates the need to use a third electric machine, the exciter, as part of the generator machine.

Claims (1)

CLAIM The axial multiphase non-contact two-input electric machine-generator contains a housing, a pathogen and a main generator mounted on one shaft mounted in a housing of the generator in bearing shields, while the pathogen consists of an axial magnetic circuit of the pathogen inductor, in the grooves of which the field excitation coil connected to the source is laid direct current, and an axial magnetic circuit with a multiphase winding of the exciter armature, the main generator consists of an axial magnetic circuit of the inductor of the main generator, in the slots of which the excitation winding of the main oscillator is connected, connected to the multiphase winding of the exciter armature through a multiphase two-half-wave rectifier, and an axial magnetic circuit with a multiphase main winding generator, while the axial magnetic circuit of the inductor of the pathogen, in the grooves of which the excitation coil of the pathogen is laid, and the axial magnetic circuit with a multiphase winding of the armature of the main generator they are firmly fixed in the housing on its lateral surface coaxially to each other, and their common axis of symmetry is the axis of symmetry of the shaft, and the axial magnetic circuit of the exciter inductor, in the grooves of which the field exciter coil is placed, is placed inside the axial magnetic circuit with a multiphase armature of the main generator armature, while the axial the magnetic circuit with a multiphase winding of the exciter armature and the axial magnetic circuit of the inductor of the main generator are rigidly fixed to the shaft through the disk coaxially to each other, while their common axis of symmetry is the axis of symmetry of the shaft, and the axial magnetic circuit with a multiphase winding of the exciter armature is located inside the axial magnetic circuit of the inductor of the main generator the fact that an additional voltage stabilizer is installed in the housing, which contains a voltage corrector and a second multiphase half-wave rectifier installed in the inner part of the axial magnetic circuit of the exciter inductor, correcting and compounding windings laid in the grooves of the axial magnetic circuit of the exciter inductor, while the input of the second multiphase half-wave rectifier is connected to the phase beginnings of the multiphase armature of the main generator, and the output is connected to the compound winding, the voltage corrector input is connected to the line voltage of any two phases of the multiphase winding main generator, and the output is connected to a correcting winding.