RU2643514C1 - Stabilized radial-axial contactless electric generator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: stabilised radial-axial contactless electric generator comprises a housing. In the lower part of the housing there is a constant-voltage regulator comprising a power supply unit for the connection to the battery, a reactor, a comparator, a saw-toothed wave former, whose output is connected to an inverting input of the comparator, a control signal former, whose output is connected to a non-inverting input of the comparator, a field-effect transistor, whose base is connected to the output of the comparator, and an emitter is connected to the positive output of a multiphase full-wave rectifier. The collector of the field-effect transistor is connected to the first terminal of the reactor, to the second terminal of which a smoothing capacitor is connected. The comparator is executed on the first operational amplifier. The saw-toothed wave former comprises a square-wave generator consisting of the second operational amplifier, the first positive feedback resistor connected to the output and non-inverting input of the second operational amplifier. A saw-toothed wave generator consists of the third operational amplifier, the second positive feedback resistor connected to the output of the third operational amplifier and non-inverting input of the second operational amplifier, integrating capacitor of negative feedback connected to the output and inverting input of the third operational amplifier. A voltage divider connected to the power supply unit consists of the first and second resistors, whose output is connected to the inverting input of the second operational amplifier and non-inverting input of the third operational amplifier. The resistor is connected to the output of the second operational amplifier and the inverting input of the third operational amplifier. The generator control signal former comprises the fourth operational amplifier, an adjustable resistor connected to the power supply unit, the first voltage-dropping resistor connected to the positive output of the rectifier and inverting input the fourth operational amplifier. The second voltage-dropping resistor is connected to the adjustable resistor and non-inverting input of the fourth operational amplifier. The negative feedback resistor is connected to the output and inverting input of the fourth operational amplifier. A bias resistor is connected to the non-inverting input of the fourth operational amplifier, which determines the magnitude of the voltage bias at the non-inverting input of the fourth operational amplifier.

EFFECT: extension of operational capabilities.

4 cl, 5 dwg

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 electrical DC energy.

Known axial two-input non-contact electric machine-generator (RF patent No. 2450411, authors Gayt B.Kh., Kashin Ya.M. et al.), Comprising a housing, a shaft mounted in bearing assemblies, on which a pathogen, pathogen and main generator are installed in this case, 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 first 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, and 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 main generator, are made axial, while the lateral axial magnetic circuits are rigidly installed in case, and the permanent multipolar magnet of the exciter exciter and the internal axial magnetic circuit are rigidly mounted on the shaft with possibly rotation relative to the lateral axial magnetic circuits, with the permanent multipolar magnet of the exciter inductor installed at the end of one side axial magnetic circuit, and the internal axial magnetic circuit 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, made with two active end surfaces with grooves, and the other lateral axial The main magnetic circuit is made with one active end surface with grooves, while 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, which is connected to the coil, is laid on the opposite side. pathogen through a multiphase half-wave rectifier, and an additional excitation winding of the pathogen connected to the source at a direct current, in the grooves of the internal axial magnetic circuit from the side of the exciter winding and the additional excitation winding of the pathogen, a multiphase winding of the exciter armature is laid, and on the opposite side, a single-phase excitation winding of the main generator is placed, which is connected to the exciter winding of the exciter through a multiphase two-half-wave rectifier, multiphase windings of the lateral axial magnetic circuit with one active end surface laid multiphase winding of the armature of the main generator ora.

However, this well-known axial two-input non-contact electric generator machine does not have good mass and dimensions due to the placement of an axial permanent multipolar magnet on the rotor along with an axial magnetic circuit with a multiphase winding of the exciter armature, while the space inside the axial magnetic circuits remains free. The length of this space is equal to the length of the generator machine, and the diameter is:

since in the manufacture of an axial electric machine that is optimal in terms of maximum specific power, the main ratio of the outer and inner diameters is:

where D _H is the outer diameter of the axial magnetic cores, D _B is the inner diameter of the axial magnetic cores. (Kashin Ya.M., Kashin A.Ya., Paukov D.V. Justification and development of promising constructions of generator sets for autonomous power supply systems. // Izv. Universities. Electromechanics. 2012. No. 1. P. 46-53.)

Closest to the claimed invention in technical essence and adopted by the authors for the prototype is a radial-axial two-input non-contact electric generator machine (US Pat. RF No. 2585222, publ. 05.27.2016), containing a housing, an internal axial magnetic circuit with two active end surfaces , a shaft mounted in bearing assemblies on which a pathogen, pathogen and main generator are mounted, while the pathogen consists of a permanent multipolar magnet of the pathogen inductor and magnetically wires, in the slots of which the multiphase winding of the exciter armature is laid, the pathogen consists of a lateral axial magnetic circuit rigidly fixed in the housing, the additional single-phase excitation winding of the pathogen and the main single-phase excitation winding connected through a multiphase two-half-wave rectifier to the multiphase exciter and multiphase winding of the armature of the pathogen, laid in the grooves of the internal axial magnetic circuit with two active end surfaces, the main generator consists of a single-phase excitation winding of the main generator, laid in the grooves of the internal axial magnetic circuit with two active end surfaces and connected through a multiphase half-wave rectifier to the multiphase winding of the exciter armature, and a lateral axial magnetic circuit rigidly fixed in the housing with one end active surface, in the grooves of which are laid the multiphase winding of the armature of the main generator connected to the multiphase half-wave output to the frame, wherein the internal axial magnetic circuit with two active end surfaces is mounted between the lateral axial magnetic circuits and is rigidly connected to the shaft via a disk, while the single-phase excitation winding of the main generator is laid in the grooves of the internal axial magnetic circuit with two active end surfaces from the side axial magnetic circuit with a multiphase winding anchors of the main generator, and the multiphase winding of the pathogen armature is laid in the grooves of the internal axial magnesium the top conductor with two active end surfaces from the side of the axial side magnetic circuit with the main and additional single-phase excitation windings of the pathogen, the shaft is hollow, the lateral axial magnetic circuit, in the grooves of which are laid the main and additional single-phase excitation windings of the exciter, is made with one active end surface, and a fixed axis is installed in the housing, located coaxially with the hollow shaft, which can rotate around a fixed axis, while the fixed axis z it is mounted in bearing assemblies installed in the hollow shaft and is rigidly connected to the housing by one end located on the housing side, on which a lateral axial magnetic circuit with a multiphase winding of the armature of the main generator is fixed, which is connected to a multiphase two-half-wave rectifier, and the magnetic circuit, in the grooves of which is laid the multiphase winding of the exciter armature is made cylindrical and rigidly fixed on a fixed axis, while the permanent multipolar magnet of the exciter exciter is mounted on the inside the surface of the hollow shaft in such a way that the magnetic flux generated by the permanent multipolar magnet of the exciter inductor is directed along the radius of the cylindrical magnetic circuit with a multiphase winding of the exciter exciter.

However, the output voltage of such a generator machine depends on the frequency of rotation of the permanent multipolar magnet of the exciter exciter and the internal axial magnetic circuit with a multiphase winding of the exciter armature and a single-phase excitation winding of the main generator:

where C is the design coefficient, w is the rotation frequency, Φ is the magnetic flux of excitation.

This limits the scope of the electric generator machine: the known electric generator machine can be used to power consumers that are not critical to the quality of the rectified voltage.

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.

The objective of the proposed invention is to expand the scope of the radial-axial non-contact electric generator.

The technical result of the claimed invention is the stabilization of the rectified voltage.

The technical result is achieved by the fact that in the lower part of the housing of the proposed stabilized radial-axial non-contact electric generator, comprising a housing, an internal axial magnetic circuit with two active end surfaces, a hollow shaft mounted in bearing assemblies on which a pathogen, exciter and main generator are mounted rigidly the fixed axis connected to the housing at one end, located coaxially with the hollow shaft, which can rotate around it, and fixed in bearings mounted in a hollow shaft, wherein the exciter consists of a cylindrical magnetic circuit with a multiphase winding of the exciter armature, rigidly mounted on a fixed axis, and a permanent multipolar magnet of the exciter exciter installed on the inner surface of the hollow shaft in such a way that the magnetically generated inductor of the exciter excitation the flow is directed along the radius of the cylindrical magnetic circuit with a multiphase winding of the exciter armature, pathogen consists of a lateral axial magnetic circuit rigidly fixed in the housing with one active end surface, in the grooves of which a single-phase excitation winding of the pathogen is connected, connected through a multiphase two-half-wave rectifier to a multiphase winding of the exciter armature, and a multiphase winding of the exciter armature, laid in the grooves of the two axial axial paths end surfaces, the main generator consists of a single-phase excitation winding of the main generator, laid in grooves in a morning axial magnetic circuit with two active end surfaces and connected through a multiphase two-half-wave rectifier to a multiphase winding of the exciter armature, and rigidly fixed in the housing of the lateral axial magnetic circuit with one end active surface, in the slots of which a multiphase winding of the armature of the main generator is connected, connected to a multiphase two-phase moreover, the internal axial magnetic circuit with two active end surfaces is installed between the side axial magnetic circuits and is rigidly connected to the hollow shaft through the disk, while the single-phase excitation winding of the main generator is laid in the grooves of the internal axial magnetic circuit with two active end surfaces from the side axial magnetic circuit with a multiphase winding of the main generator armature, and the multiphase winding of the exciter armature is laid in the grooves internal axial magnetic circuit with two active end surfaces from the side of the lateral axial magnetic circuit with single-phase with the exciter winding of the pathogen, an additional voltage stabilizer is installed, comprising a power supply unit configured to be connected to a storage battery, providing power to the electronic elements of the voltage stabilizer, a reactor, a comparison unit, a sawtooth signal generation unit, the output of which is connected to the inverting input of the comparison unit, the formation unit control signal, the output of which is connected to the non-inverting input of the comparison unit, a field effect transistor, the base of which is under It becomes active to the output of the comparator and an emitter connected to the positive output of the multiphase full-wave rectifier, the field tranizistora collector connected to the first terminal of the reactor, to the second terminal of which is adapted to connect to a battery, a smoothing capacitor is connected.

The comparison unit of the proposed stabilized radial-axial non-contact electric generator is performed on the first operational amplifier, and the sawtooth signal generation unit contains:

- a rectangular pulse generator, consisting of a second operational amplifier of a rectangular pulse generator, a first positive feedback resistor connected to the output and non-inverting input of a second operational amplifier of a rectangular pulse generator;

- a sawtooth signal generator, consisting of a third operational amplifier of a sawtooth signal generator, a second positive feedback resistor connected to the output of a third operational amplifier of a sawtooth signal generator and a non-inverting input of a second operational amplifier of a rectangular pulse generator, integrating a negative feedback capacitor connected to the output and inverting the input of the third operational amplifier of the sawtooth signal generator;

- a voltage divider connected to the power supply unit, consisting of the first and second resistors of the voltage divider, the output of which is connected to the inverting input of the second operational amplifier of the rectangular pulse generator and to the non-inverting input of the third operational amplifier of the sawtooth signal generator;

- a resistor connected to the output of the second operational amplifier of the rectangular pulse generator and the inverting input of the third operational amplifier of the sawtooth signal generator.

The control signal generating unit (BFUS) contains

- the fourth operational amplifier generating a control signal;

- an adjustment resistor connected to the power supply;

- the first step-down resistor connected to the positive output of the multiphase half-wave rectifier and the inverting input of the fourth operational amplifier generating the control signal;

- a second step-down resistor connected to an adjustment resistor and a non-inverting input of a fourth operational amplifier for generating a control signal;

- a negative feedback resistor connected to the output and inverting input of the fourth operational amplifier generating the control signal;

- a bias resistor connected to a non-inverting input of the fourth operational amplifier for generating a control signal, which determines the amount of voltage bias at the non-inverting input of the fourth operational amplifier for generating a control signal.

Stabilization of the rectified voltage is carried out at the output of the voltage stabilizer by changing the duty cycle of the pulses on the emitter of the field effect transistor. To do this, in the comparison unit, a sawtooth signal generated by the sawtooth signal generation unit is compared with a direct voltage control signal generated by the control signal generation unit depending on the deviation of the actual value of the rectified voltage from the set value. The signal at the output of the comparison unit is control, and the signal at the output of the field effect transistor is a power signal. In this case, the frequency and duty cycle of the pulses of the control and power signals are formed the same.

In FIG. 1 shows a general view of the proposed stabilized radial-axial non-contact electric generator, FIG. 2 is a circuit diagram of a stabilized radial axial non-contact electric generator according to the invention; FIG. 3 is an electrical diagram of an output voltage stabilization unit; FIG. 4 - the principle of pulse-width modulation of the signal in the stabilizer, in FIG. 5 - the principle of the formation of pulse-width modulation of the signal in the stabilizer when the value of the rectified voltage changes.

A stabilized radial-axial non-contact electric generator contains: a housing 1, an internal axial magnetic circuit 2 with two active end surfaces, a hollow shaft 3, mounted in the bearing assemblies 4, on which a pathogen, exciter and main generator are mounted rigidly connected to the housing 1 at one end by a fixed axis 5, located coaxially with the hollow shaft 3, having the possibility of rotation around it, and fixed in the bearing units 6 installed in the hollow shaft 3.

The exciter consists of a cylindrical magnetic circuit 8 with a multiphase winding 9 of the exciter armature, rigidly fixed to the fixed axis 5, and a permanent multipolar magnet 7 of the exciter exciter installed on the inner surface of the hollow shaft 3 so that the magnetic flux generated by the permanent multipolar magnet 7 of the excitator inducer is directed along the radius of the cylindrical magnetic circuit 8 with a multiphase winding 9 anchor exciter.

The pathogen consists of a lateral axial magnetic circuit 10 rigidly fixed in the housing 1 with one active end surface, in the grooves of which a single-phase excitation winding 11 of the activator is connected, connected through a multiphase two-half-wave rectifier 12 to the multiphase winding 9 of the exciter armature, and a multiphase winding 13 of the exciter armature grooves of the internal axial magnetic circuit 2 with two active end surfaces.

The main generator consists of a single-phase excitation winding 14 of the main generator, laid in the grooves of the internal axial magnetic circuit 2 with two active end surfaces and connected through a multiphase half-wave rectifier 15 to the multiphase winding 13 of the exciter armature, and a lateral axial magnetic circuit 16 rigidly fixed in the housing 1 with one end the active surface, in the grooves of which the multiphase winding 17 of the armature of the main generator is laid, connected to the multiphase half-wave rectifier Ielu 18, wherein the internal axial magnetic circuit 2 with two active end surfaces is mounted between the lateral axial magnetic circuits 10 and 16 and is rigidly connected to the hollow shaft 3 via the disk 19, while the single-phase excitation winding 14 of the main generator is laid in the grooves of the internal axial magnetic circuit 2 with two active end surfaces from the side of the lateral axial magnetic circuit 16 with a multiphase winding 17 of the armature of the main generator, and a multiphase winding 13 of the armature of the pathogen laid in the grooves of the internal axial magnetic circuit 2 with two active end surfaces from the side of the lateral axial magnetic circuit 10 with a single-phase excitation winding 11 of the pathogen.

In the lower part of the housing 1, a voltage stabilizer 20 is installed, comprising a power supply unit (PSU) 21, configured to be connected to a storage battery (AB) 22, providing power to the electronic elements of the voltage stabilizer 20, reactor 24, a comparison unit (BSR) 26, a forming unit sawtooth signal (BFPS) 28, the output of which is connected to the inverting input of the comparison unit (BSR) 26, the control signal generating unit (BFUS) 37, the output of which is connected to the non-inverting input of the BSR 26, field-effect transistor 23 (VT1), the base of which is it is connected to the output of the BSR 26, and the emitter is connected to the positive output of the multiphase half-wave rectifier 18, while the collector of the field-effect transistor 23 is connected to the first terminal of the reactor 24, to the second terminal of which, configured to connect to AB 22, a smoothing capacitor 25 (C2) is connected .

The input of the PSU 21 is connected to the AB 22 (is not part of the proposed electric generator machine).

BSR 26 is made on the first operational amplifier 27 (OP1).

BFPS 28 contains:

- a rectangular pulse generator, consisting of a second operational amplifier 34 (OP2) of a rectangular pulse generator, a first positive feedback resistor 32 (R9) connected to the output and non-inverting input of a second operational amplifier 34 (OP2) of a rectangular pulse generator;

- a sawtooth signal generator, consisting of a third sawtooth signal amplifier 29 (OP3), a second positive feedback resistor 30 (R10) connected to the output of a third sawtooth signal amplifier 29 (OP3) and a non-inverting input of the second operational amplifier 34 (OP2 ) a rectangular pulse generator integrating a negative feedback capacitor 36 (C1) connected to the output and inverting input of the third operational amplifier 29 (OP3) of the generator saw figurative signal;

- a voltage divider connected to the BP 21, consisting of the first 35 (R6) and second 33 (R8) resistors of the voltage divider, the output of which is connected to the inverting input of the second operational amplifier 34 (OP2) of the square-wave generator and to the non-inverting input of the third operational amplifier 29 ( OP3) sawtooth signal generator;

- a resistor 31 (R7) connected to the output of the second operational amplifier 34 (OP2) of the square-wave generator and the inverting input of the third operational amplifier 29 (OP3) of the sawtooth signal generator.

BFUS 37 contains:

- the fourth operational amplifier 43 (OP4) generating a control signal;

- adjusting resistor 39 (R3) connected to the PSU 21;

- the first step-down resistor 40 (R1) connected to the positive output of the multiphase half-wave rectifier 18 and the inverting input of the fourth operational amplifier 43 (OP4) generating the control signal;

- the second step-down resistor 41 (R4) connected to the control resistor 39 (R1) and the non-inverting input of the fourth operational amplifier 43 (OP4) generating the control signal;

- negative feedback resistor 42 (R2) connected to the output and inverting input of the fourth operational amplifier 43 (OP4) generating the control signal;

- bias resistor 38 (R5) connected to the non-inverting input of the fourth operational amplifier 43 (OP4) generating a control signal, which determines the amount of voltage offset at the non-inverting input of the fourth operational amplifier 43 (OP4) generating a control signal.

The first 35 (R6) and second 33 (R8) resistors of the BPSF voltage divider 28 are selected of the same value and are selected so that half the supply voltage from BP 21 is supplied to the inverting input of the second operational amplifier 34 (OP2) of the square-wave generator.

The second operational amplifier 34 (OP2) of the square-wave generator due to the positive feedback provided by the first 30 (R10) and second 32 (R9) positive feedback resistors operates in the generator mode, producing rectangular pulses to the inverting input of the third operational amplifier 29 (OP3 ) through resistor 31 (R7). The first 30 (R10) and second 32 (R9) positive feedback resistors also affect the ramp height relative to zero.

The third operational amplifier 29 (OP3) of the sawtooth signal generator operates in integrator mode, converting the square-wave pulses at the output of the second operational amplifier 34 (OP3) of the square-wave generator into a sawtooth signal (Figs. 4 and 5 - U _outfBPS ). The negative feedback integrating capacitor 36 (C1) of the third operational amplifier 29 (OP3) of the sawtooth signal generator determines the frequency of the rectangular pulses and, accordingly, the frequency of the sawtooth signal. The smaller the capacitance of the integrating capacitor 36 (C1), the higher the frequency of the sawtooth signal, and vice versa. The frequency of this sawtooth signal determines the pulse frequency of the reference signal.

Thus, in the BFPS 28, a sawtooth waveform U of the _{outBFPS is generated} (Fig. 4).

- и должны быть равны между собой. Резистор 38 (R5) смещения, подключенный к неинвертирующему входу четвертого операционного усилителя 43 (ОР4) формирования управляющего сигнала, определяет величину смещения напряжения на неинвертирующем входе четвертого операционного усилителя 43 (ОР1) формирования управляющего сигнала. Резистор 42 (R2) отрицательной обратной связи, подключенный к выходу и инвертирующему входу четвертого операционного усилителя 43 (ОР4) формирования управляющего сигнала обеспечивает его устойчивую работуIn BFUS 37, a control signal is generated, the voltage level of which depends on the voltage at the output of the multiphase half-wave rectifier 18. The adjustment resistor 39 (R1) manually sets the specified voltage at the output of the multiphase half-wave rectifier 18, with respect to which stabilization is carried out. The first 40 (R1) and second 41 (R4) step-down resistors are selected so that the voltage at the inverting and non-inverting inputs of the fourth operational amplifier 43 (OP4) is equal, provided that the voltage at the output of the multiphase half-wave rectifier 18 is equal to that set by the control resistor 39 ( R3). The nominal resistance of the first 40 (R1) and second 41 (R4) step-down resistors determine the value of the gain of the fourth operational amplifier 43 (OP4) -

- and should be equal to each other. The bias resistor 38 (R5) connected to the non-inverting input of the fourth operational amplifier 43 (OP4) generating the control signal determines the amount of voltage bias at the non-inverting input of the fourth operational amplifier 43 (OP1) generating the control signal. A negative feedback resistor 42 (R2) connected to the output and inverting input of the fourth operational amplifier 43 (OP4) generating the control signal ensures its stable operation

In the first operational amplifier 27 (OP1) BSR 26 compares the voltage level of the sawtooth signal taken from the output of the third operational amplifier 29 (OP3) BFPS 28, with the voltage level of the control signal taken from the output of the fourth operational amplifier 43 (OP4) BFUS 37, the value which depends on the deviation of the actual value of the rectified voltage taken from the output of the multiphase half-wave rectifier 18, given by the control resistor 39 (R3). Moreover, the greater the gain k, the narrower the control window will be, the faster the duty cycle of the output pulse signal at the output of the first operational amplifier 27 (OP1) of the BSR 26 will change from minimum to maximum value with small deviations of the voltage at the output of the multiphase half-wave rectifier 18 from set level.

In FIG. 4, 5 are indicated: U _outbfps - signal at the output of BFPS 28, U _outbfus - signal at the output of BFUS 37, U _outbss - signal at the output of BSR 26.

The parameters of the elements of the voltage stabilizer 20 are selected so that when the voltage at the output of the multiphase half-wave rectifier 18 is equal to that specified by the control resistor 39 (R3), the level of the control signal at the output of the BFUS 38 is located in the middle of the sawtooth signal (Fig. 4, the upper graph) generated by the BFPS 28. In this case, the duration of the pulses at the output IWU 26 is the pause length (Fig. 4, lower panel), so the possibility of stabilizing the output voltage of the generator as a U _OUT decreases and when y elichenii voltage Uin taken from the positive output of the multiphase full-wave rectifier 18, a predetermined relative adjusting resistor 39 (R3) value will be identical.

Stable radial-axial non-contact electric generator operates as follows.

When rotating the hollow shaft 3, mounted in the housing 1 in the bearing units 4, with a permanent multi-pole magnet 7 of the exciter inductor mounted on its inner surface, and an internal axial magnetic circuit 2 with a multiphase winding 13 of the exciter armature and a single-phase excitation winding 14 of the main generator, rigidly connected with a hollow shaft 3 by means of a disk 19, the magnetic flux generated by the permanent multipolar magnet 7 of the exciter exciter and directed along the radius of the rigidly fixed at coaxially with the hollow shaft 3 of the fixed axis 5 of the cylindrical magnetic circuit 8, in the grooves of which a multiphase winding 9 of the exciter armature is laid, interacts with it, and induces a multiphase EMF system in it. This EMF is rectified by a multiphase half-wave rectifier 12 and is supplied to a single-phase exciter winding 11 placed in the grooves of the lateral axial magnetic circuit 10. In this case, a magnetic flux is generated in the single-phase excitation winding 11. This magnetic flux interacts with the multiphase winding 13 of the exciter armature, laid in the grooves of the internal axial magnetic circuit 2, and induces a multiphase EMF system in it, which is rectified by the multiphase half-wave rectifier 15 and fed to the single-phase excitation winding 14 of the main generator, laid in the grooves of the internal axial magnetic circuit 2 with two active end surfaces from the side of the lateral axial magnetic circuit 16 with a multiphase winding 17 of the armature of the main generator. The magnetic flux of a single-phase excitation winding 14 of the main generator interacts with the multiphase winding 17 of the armature of the main generator and induces a multiphase EMF system in it, which is rectified by a multiphase half-wave rectifier 18.

Stabilization of the rectified voltage is as follows.

In the BSR 26, a sawtooth signal is compared, taken from the output of the third operational amplifier 29 (OP3) of the BFPS 28, with a direct-current control signal, taken from the output of the fourth operational amplifier 43 (OP4) of the BFUS 37.

Depending on the voltage level U _VX at the input of the voltage stabilizer 20, the duty cycle of the pulse signal is changed at the output of the BDS 26, i.e. the output signal of the BDS 26 is a pulse width modulated (PWM signal). This leads to a change in the open time of the field effect transistor 23 (VT1).

If the voltage at the output of the multiphase half-wave rectifier 18 (at the input of the voltage stabilizer 20) falls below the level set by the control resistor 39 (R3), then the level of the positive signal at the inverting input of the fourth operational amplifier 43 (OP4) decreases. Therefore, the level of the positive signal at the output of the fourth operational amplifier 43 (OP4) increases. This increased signal is fed to the non-inverting input of the first operational amplifier 27 (OP1) BSR 26.

The first operational amplifier 27 (OP1) of the BSR 26 operates in a comparator mode. With an increase in the level of the signal supplied to the non-inverting input of the first operational amplifier 27 (OP1), the duty cycle of the pulses at its output decreases (duty cycle increases accordingly) (Fig. 5a). Reduced duty cycle pulse signal is supplied to the base of the FET 23 (VT1), as a result of the open state of the FET 23 (VT1) increases, the output voltage U _OUT taken from the output of the stabilizer 20 increases to a predetermined value.

If the voltage at the output of the multiphase half-wave rectifier 18 becomes higher than the level set by the control resistor 39 (R3), the process proceeds similarly - the duty cycle increases, the duty cycle decreases (Fig. 5b), the open time of the field-effect transistor 23 (VT1) also decreases, the output voltage U _OUT decreases to the set value.

During transients during voltage stabilization, the reactor 24 (L1) smoothes the current ripple at the output of the field effect transistor 23 (VT1), and the smoothing capacitor 25 (C2) smoothes the voltage ripple, providing high quality rectified voltage at the output of the voltage stabilizer 20.

This is as follows. Reactor 24 (L1) is a large inductance coil. With a sharp increase in the current flowing through the field effect transistor 23 (VT1), to the collector of which the first terminal of the reactor 24 (L1) is connected, the second terminal of which is connected to the positive output terminal of the voltage regulator 20, the current in the reactor 24 (L1) also begins to increase. However, due to the large inductance, the reactor 24 (L1) prevents a sharp increase in the current in it, so during the pulse the current does not increase immediately, but gradually (according to the exponential law), but during a pause between pulses, when the current in the field-effect transistor 23 (VT1) does not flow, the current in the reactor 24 (L1) also decreases not sharply, but gradually (according to the exponential law). Thus, the reactor 24 (L1) provides smoothing of the ripple current at the output of the voltage regulator 20.

The smoothing capacitor 25 (C2) of one of the plates is connected to the second terminal of the reactor 24 (L1) and to the positive output terminal of the voltage stabilizer 20, and the second plate of the capacitor 25 (C2) is grounded. During the pulse, when the field effect transistor 23 (VT1) is open, a potential difference arises between the positive and negative output terminals of the voltage stabilizer 20, but the smoothing capacitor 25 (C2), being in the discharged state, begins to charge and thereby prevents a sharp change in the potential difference. During a pause between pulses, when the field-effect transistor 23 (VT1) is closed, the potential difference between the positive and negative output terminals of the voltage stabilizer 20 disappears, but the smoothing capacitor 25 (C2), being in a charged state, starts to discharge and thereby prevents a sharp change in the difference potentials. Thus, the smoothing capacitor 25 (C2) provides smoothing of the ripples of the rectified voltage, ensuring its high quality.

High quality rectified voltage is supplied to the network and to the AB 22 to recharge it.

The present invention, performing the function of converting the mechanical energy of rotation into electrical energy of direct current, like the prototype, at the same time, unlike it due to the stabilization of its output voltage, allows us to expand the scope of the generator, for example, for use in facilities where the stability of constant voltage is essential.

Claims (4)

1. A stabilized radial-axial non-contact electric generator comprising a housing, an internal axial magnetic circuit with two active end surfaces, a hollow shaft mounted in bearing assemblies, on which a pathogen, exciter and main generator are mounted rigidly connected to the housing at one end by a fixed axis located coaxially with the hollow shaft, which can be rotated around it, and fixed in the bearing units installed in the hollow shaft, while the exciter consists of tsil a magnetic core with a multiphase winding of the exciter exciter armature, rigidly fixed on the fixed axis, and a permanent multipolar magnet of the exciter exciter mounted on the inner surface of the hollow shaft so that the magnetic flux generated by the permanent multipolar magnet of the exciter exciter is directed along the radius of the cylindrical exciter of the exciter, multi-phase winding the pathogen consists of a lateral axial magnetic circuit rigidly fixed in the housing with one the active end surface, in the grooves of which a single-phase excitation winding of the pathogen is connected, connected through a multiphase two-half-wave rectifier to the multiphase winding of the exciter armature, and a multiphase winding of the exciter armature, laid in the grooves of the internal axial magnetic circuit with two active end surfaces of the excitation core, the main generator consists of the main generator, laid in the grooves of the internal axial magnetic circuit with two active end surfaces and along connected through a multiphase two-half-wave rectifier to a multiphase winding of the exciter armature, and a lateral axial magnetic circuit rigidly fixed in the housing with one end active surface, into the slots of which a multiphase winding of the main generator armature is connected, connected to a multiphase two-half-wave rectifier, with an internal axial axial magnetic circuit with installed between the lateral axial magnetic circuits and is rigidly connected to the hollow shaft by means of a disk, and the single-phase excitation winding of the main generator is laid in the grooves of the internal axial magnetic circuit with two active end surfaces from the side axial magnetic circuit with the multiphase armature of the main generator, and the multiphase armature of the exciter is laid in the grooves of the internal axial magnetic circuit with two active end surfaces on the side of the axial magnetic circuit with a single-phase excitation winding of the pathogen, characterized in that in the lower part of the housing a voltage stabilizer comprising a power supply unit configured to be connected to a storage battery, providing power to the electronic elements of a voltage stabilizer, a reactor, a comparison unit, a sawtooth signal generating unit, the output of which is connected to the inverting input of the comparison unit, a control signal generating unit, the output of which is connected to the non-inverting input of the comparison unit, a field effect transistor whose base is connected to the output of the comparison unit, and the emitter is connected to the positive at the output of a multiphase half-wave rectifier, while the collector of the field-effect transistor is connected to the first terminal of the reactor, to the second terminal of which, made with the possibility of connecting to the battery, a smoothing capacitor is connected. 2. The stabilized radial-axial non-contact electric generator according to claim 1, characterized in that the comparison unit is made on the first operational amplifier. 3. The stabilized radial-axial non-contact electric generator according to claim 1, characterized in that the sawtooth signal generating unit comprises a rectangular pulse generator consisting of a second operational amplifier of a rectangular pulse generator, a first positive feedback resistor connected to an output and a non-inverting input of a second operating a rectangular pulse generator amplifier, a sawtooth signal generator, consisting of a third operational amplifier of a saw generator a typical signal, a second positive feedback resistor connected to the output of the third operational amplifier of the sawtooth signal generator and a non-inverting input of the second operational amplifier of the rectangular pulse generator, an integrating negative feedback capacitor connected to the output and inverting input of the third operational amplifier of the sawtooth generator, connected to the block voltage divider consisting of the first and second resistors of the voltage divider I, the output of which is connected to the inverting input of the second operational amplifier rectangular pulse generator and to the noninverting input of the third operational amplifier ramp signal generator, a resistor connected to the output of the second operational amplifier square wave generator and the inverting input of third operational amplifier ramp signal generator. 4. The stabilized radial-axial non-contact electric generator according to claim 1, characterized in that the control signal generating unit comprises a fourth operational signal generating amplifier, an adjustment resistor connected to the power supply, a first step-down resistor connected to the positive output of the multiphase half-wave rectifier and the inverting input of the fourth operational amplifier of the formation of the control signal, the second step-down resistor connected to the regulation a pull-up resistor and a non-inverting input of the fourth operational amplifier for generating a control signal, a negative feedback resistor connected to the output and inverting input of a fourth operational amplifier for generating a control signal; a bias resistor connected to a non-inverting input of the fourth operational amplifier for generating a control signal, which determines the amount of voltage bias at the non-inverting input of the fourth operational amplifier for generating a control signal.

Images