RU2605764C1 - Parametric resonance generator and method of exciting electric oscillations in generator - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, to resonant converters of electric energy based on parametric resonance generators. Parametric resonance generator comprises a set of coils interconnected in series and forming a resonance circuit with a capacity. Device for periodic changing the resonance circuit inductance is installed on the electric motor axle. Parametric resonance generator and the device for periodic changing the resonance circuit inductance are made of the first and the second parametric resonance electric machines installed one above the other. Each of the electric machines has a stator and a rotor. Rotors of the two electric machines are mounted on a common shaft. In stator slots of the first and the second electric machines around stator teeth there are main inductance coils connected to each other and to the capacity into a separate resonance circuit of each electric machine. Each main inductance coil in the second electric machine has an additional winding. All additional windings of all inductance coils of the second electric machine are interconnected in series and together with the main inductance coils are made in the form of a Tesla resonance transformer, wherein the main inductance coils of the resonance circuit are the primary winding. Additional windings of the inductance coils are made in the form of a secondary winding. Outputs of the Tesla transformer secondary winding are connected via a rectifier or one more Tesla transformer, a rectifier and an inverter to the load and via a frequency converter with the resonance circuit of the inductance coils of the first electric machine. Rotors of the first and the second electric machines in the cross section have on the outer rim ledges and slots. Dimensions of a rotor ledge are equal to the total size of two teeth and two slots of a stator. Number of a rotor ledges is twice less than the number of a stator teeth in each electric machine.

EFFECT: technical result is improvement of power and decrease of dependence of produced power of the parametric resonance generator from the load.

6 cl, 3 dwg

Description

The invention relates to electrical engineering, in particular to resonant converters of electrical energy based on parametric resonant generators.

, где к - коэффициент усиления одного каскада (Резонансный усилитель мощности. Пат. РФ №2517378, заявл. 17.10.2012, опубл. 27.05.2014. Бюл. №15).Known resonant power amplifier containing input and power transformers with a load in the secondary winding of the power transformer and a series resonant circuit between transformers, consisting of a capacitance C and inductance of the input winding of the power transformer, as well as from a feedback device between the windings of the input and power transformer, a resonant amplifier power contains n amplification stages of n step-down power transformers, interconnected using n consecutive resonance nth circuits, where n = 2, 3, ... m, and the feedback is made in the form of a device providing unidirectional movement of electric energy from the secondary winding of the last power transformer to the primary winding of the input transformer, the power of each subsequent n-th power transformer is related to the power of the previous n-1st power transformer ratio:

, where k is the gain of one cascade (Resonant power amplifier. Pat. RF No. 2517378, decl. 17.10.2012, publ. 05.27.2014. Bull. No. 15).

In the embodiment of the resonant power amplifier, the feedback device is made in the form of an uninterruptible power supply unit, the input of which is connected to the secondary winding of the last power transformer, and the output to the primary winding of the input transformer. In another embodiment of the resonant power amplifier, the feedback device is made in the form of a unidirectional inductance, the input of which is connected to the secondary winding of the last power transformer, and the output to the primary winding of the input transformer.

A disadvantage of the known device is the large mass of cores and coils and a low gain.

Closest to the proposed invention is a parametric resonance generator, consisting of two groups of flat self-induction coils with an iron core connected to a capacitance and forming a resonant circuit, self-induction coils are installed on two parallel planes along the periphery of two parallel circles, between the sides of the coils facing each other a narrow space in the form of a slit in which a flat metal disk with rotation is placed, having a notch in the form of a tooth at the periphery c, the number of teeth is equal to the number of pairs of coils, the middle of the teeth is located on a circle coinciding with the circle passing through the center of the self-induction coils (I. Grekov. Resonance. - Gosenergoizdat, 1952, p. 60-84).

Known parametric resonant generator uses the phenomenon of parametric excitation of oscillations due to periodic changes in the inductance of the resonant circuit.

A disadvantage of the known parametric resonant generator is limited power due to the nonlinear dependence of the inductance of the iron core coil on the current in the inductor. Another disadvantage is the decrease in the quality factor of the resonant circuit due to the inclusion of load resistance in the circuit of the resonant circuit.

The objective of the invention is to increase power and reduce the dependence of the generated electricity of a parametric resonant generator on the magnitude of the load.

The technical result consists in increasing power and stabilizing the amount of generated energy when the load changes.

The technical result is achieved in that in the proposed parametric resonant generator containing a group of coils connected in series and forming a resonant circuit and a device for periodically changing the inductance of the resonant circuit mounted on the axis of the electric motor, a parametric resonant generator and a device for periodically changing the inductance of the resonant circuit are made of the first and a second parametric resonant electric machines mounted one above the other, as waiting for electric machines has a stator and rotor, the rotors of two electric machines are mounted on a common shaft, in the grooves of the stator of the first and second electric machines around the stator teeth are installed the main inductors, which are connected to each other and to the capacitance in a separate resonant circuit of each electric machine, each the main inductor in the second electric machine has an additional winding, all additional windings of all inductors of the second electric machine are connected in series and together with the main inductors made in the form of a Tesla resonant transformer, in which the main inductors of the resonant circuit are the primary winding, and the additional windings of the inductors are made in the form of a secondary winding, the terminals of the secondary winding of the Tesla transformer are connected through a rectifier or another Tesla transformer, rectifier and an inverter with a load and through a frequency converter with a resonant circuit of the inductors of the first electric machine, rotors The second and the second electric machines in cross section have protrusions and grooves on the outer rim, the size of the rotor protrusion is equal to the total size of two teeth and two stator grooves, and the number of rotor protrusions is half the number of stator teeth in each electric machine.

In a variant of a parametric resonant generator, the stators and rotors of the first and second parametric resonant electric machines are made of ferromagnetic material, in which the inductance of the coils is independent of the current in the coil in the frequency range 0-10 kHz, for example, of ferrite.

In another embodiment of a parametric resonant generator, the stators of the first and second parametric resonant electric machines are made of insulating material, such as fiberglass.

In another embodiment of a parametric resonant generator, the rotors of the first and second parametric resonant electric machines are made of non-magnetic material, for example, titanium or aluminum alloy.

In a variant of a parametric resonant generator, the rotors of the first and second parametric resonant electric machines are made of insulating material, for example fiberglass, and the rims of the rotors with grooves and protrusions are made of ferromagnetic material.

In the method of exciting electric oscillations in a parametric resonant generator by periodically changing the magnetic field energy and inductance of the inductance coils of the resonant circuit with a frequency twice the frequency of the resonant circuit, in two adjacent coaxially parametric resonant electric machines, the rotors are mounted on a common shaft, in the stator slots the first and second electric machines around the stator teeth set the main inductor, connect their follower about with capacity and form a resonant circuit in each electric machine, in the second electric machine additional windings are installed on the main inductors, connect them in series so that the main and additional windings of the inductors of the second electric machine form the primary and secondary windings of the Tesla resonant transformer, conclusions Tesla transformer secondary windings are connected through a rectifier or another Tesla transformer, a rectifier, an inverter with a load and through a frequency converter with a resonant circuit of the first electric machine, alternating protrusions and grooves in the rotors of the first and second electric machines on the outer rim are two times smaller than the number of teeth and grooves of the stator, voltage is supplied from the network through the frequency converter to the resonant circuit of the first electric machine with a frequency f, at twice the resonant frequency f ₀ of the resonant circuit, and the first electric machine is used as a parametric resonance of the motor, with a aschenii rotors the first and the second electric machine rotor protrusions periodically overlap the slots and stator teeth alter the magnetic field of the stator core windings and the inductance of the resonant circuit with a frequency f, at twice the resonant frequency f ₀ of the resonant circuit parametrically excite the electromagnetic oscillations in the resonant circuit of the second electrical machines, oscillations are amplified by voltage in a Tesla resonant transformer, they are reduced by voltage in another Tesla transformer, rectified in a rectifier, reobrazuyut frequency and voltage in the inverter and supplied to the load through the inverter and the input of the resonant circuit of the first electrical machine.

The invention is illustrated in FIG. 1, FIG. 2, FIG. 3, where in FIG. 1 shows the construction of a parametric resonant generator in the form of two parametric resonant electric machines with a common shaft for two rotors.

In FIG. 2 shows an electrical block diagram of a device for periodically changing the inductance of a resonant circuit in the form of a stator and a rotor of a first parametric resonant electric machine.

In FIG. 3 shows an electrical block diagram of a second parametric resonant electric machine.

In FIG. 1 parametric resonant generator is made in the form of the first 1 and second 2 parametric resonant electric machines mounted on top of each other. Each of the electrical machines 1 and 2 has a stator 3 and a rotor 4, the rotors 3 and 4 of two electric machines 1 and 2 are mounted on a common shaft 5.

In FIG. 2, in the grooves 6 of the stator 3 of the first and second parametric resonant electric machines 1 and 2 around the teeth 7 of the stator 3, the main inductors 8 are installed, which are interconnected and with a capacity of 9 in a separate resonant circuit 10 of each electric machine 1 and 2.

In FIG. 3, each main inductor 8 in the second parametric resonant electric machine 2 has an additional winding 11, all additional windings 11 of all inductors 8 of the second electric machine 2 are connected in series and together with the main inductors 8 are made in the form of a Tesla resonant transformer 12, in which the inductors 8 of the resonant circuit 10 are the primary winding 13. Additional windings 11 of the inductors are made in the form of a secondary winding 14, output The secondary windings 14 of the Tesla transformer 12 are connected through another Tesla transformer 15, a rectifier 16 and an inverter 17 with a load of 18 and through a frequency converter 19 with a resonant circuit 10 of the inductance coils of the first electric machine.

The electrical connection of the first and second parametric resonant electric machines is shown by two arrows, position 16 in FIG. 2 and 10 in FIG. 3.

The rotors 4 of the first and second parametric resonant electric machines 1 and 2 in cross section have protrusions 20 and grooves 21 on the outer rim, the dimensions of the protrusion 20 of the rotors 4 are equal to the total size of two teeth 7 and two grooves 6 of the stator 3, and the number of protrusions 20 of the rotors 4 is 4 two times less than the number of teeth 7 of the stator 3 in each electric machine 1 and 2. The network 22 and the network switch 23 are used to turn on the frequency converter 19 and the electric machine 1 and control the speed of the rotor 4.

The stators 3 and rotors 4 of the first and second parametric resonant electric machines 1 and 2 can be made of ferromagnetic material, in which the inductance of the coils does not depend on the current in the coil in the frequency range 0-10 kHz, for example, ferrite. The stators 3 of the first and second parametric resonant electric machines 1 and 2 can be made of insulating material, for example, fiberglass. The rotors 4 of the first and second electric machines 1 and 2 can be made of non-magnetic material, for example titanium or aluminum alloy or of insulating material, for example fiberglass, and the rims of the rotors 4 with grooves 21 and protrusions 20 are made of ferromagnetic material.

The method for exciting electric oscillations in the parametric resonant generator of FIG. 1 and 2 is realized by periodically changing the magnetic field energy and inductance of the inductors 8 of the resonant circuit 10 with a frequency f twice the frequency f _{0 of the} resonant circuit 10, in two pine-parametric resonant electric machines 1 and 2 located one above the other.

The rotors 4 are installed on a common shaft 5, in the grooves 6 of the stator 3 of the first and second electric machines 1 and 2 around the teeth 7 of the stator 3, the main inductors 8 are installed, connected in series with the capacity 9 and form a resonant circuit 10 in each electric machine 1 and 2 In the second electric machine 2, additional windings 11 are installed on the main inductors 10, connected in series so that the main 10 and additional windings 11 of the inductors of the second electric machine 2 form the primary 13 and secondary 14 windings of the Tesla 12 resonant transformer, the terminals of the secondary winding 14 of the Tesla 12 transformer are connected through a Tesla 15 step-down transformer, a rectifier 16, an inverter 17 with a load of 18 and through a frequency converter 19 with a resonant circuit 10 of the first electric machine 1. In the rotors of the first 1 and the second 2 electric machines on the outer rim perform alternating protrusions 20 and grooves 21 in an amount two times less than the number of teeth 7 and grooves 6 of the stator, fed through a frequency converter 19 to the resonant circuit 10 of the first electric electric machine 1 voltage with a frequency f twice the resonant frequency f _{0 of the} resonant circuit 10, and use the first electric machine 1 as a parametric resonant electric motor, when the rotors 4 of the first 1 and second 2 electric machines rotate, the protrusions 20 of the rotor 4 periodically overlap the grooves 6 and 7, the stator tine 1, alter the magnetic field coils 8 of the stator core 3 and the inductance of the resonant circuit 10 with the frequency f, at twice the resonant frequency f ₀ of the resonant circuit parametrically excite electromagnetic oscillations in the resonant circuit 10 of the second electric machine 2 are generated, the oscillations are amplified by the voltage in the Tesla resonant transformer 12, reduced by the voltage in the Tesla transformer 15, rectified in the rectifier 16, converted in frequency and voltage to the inverter 17 and transferred to the load 18 and through a frequency converter 19 to the input of the resonant circuit 10 of the first electric machine 1.

A parametric resonant generator is a reversible electric machine and can operate both in generator mode and in electric motor mode.

In FIG. 2 and 3, the size A of each protrusion 20 on the rim of the rotor 4 is equal to the total size B of two teeth 7 and two grooves 6 of the stator 3:

The number N _{B of the} protrusions 20 of the rotor 4 is half the number of grooves 6 of the stator 3:

A parametric resonant generator operates as follows.

уменьшается, что эквивалентно уменьшению индуктивности катушек индуктивности 8. Когда в воздушном зазоре над катушками индуктивности 8 находятся пазы 21, индуктивность резонансного контура 10 становится максимальной. Изменение индуктивности резонансного контура 10 приводит к параметрическому возбуждению электромагнитных колебаний. При изменении индуктивности с частотой, в два раза большей, чем резонансная частота f₀ колебаний контура 10, в резонансном контуре 10 возникают мощные колебания с напряжением на катушке индуктивности 8 контура 10 более 10 кВ. В проводниках и в катушках индуктивности 8 резонансного контура 10 существуют хаотичные флуктации электронов, энергия и амплитуда колебаний которых пропорциональна температуре окружающей среды. Как показывает теория и опыт, в резонансном контуре 10 постоянно циркулируют беспорядочные, непрерывно меняющие свое направление, частоту и величину очень слабые флуктуационные токи величиной менее 10^-12 А, наведенные теплом окружающей среды, магнитным полем Земли, атмосферными разрядами, электрическими устройствами, радиоволнами. Параметрический резонансный генератор усиливает эти электрические колебания, что приводит к увеличению мощности в цепи.When connected to the network 22 through the switch 23, the parametric resonant electric machine operates as a parametric electric motor, and the rotors 4 of the electric machines 1 and 2 begin to rotate. The number of revolutions is regulated by the frequency converter 19. When the rotor 4 rotates, the protrusions 20 of the rotor 4 periodically overlap two adjacent inductors 8 of the stator 3 of the second electric machine 2, while the magnetic field energy

decreases, which is equivalent to a decrease in the inductance of the inductors 8. When the grooves 21 are in the air gap above the inductors 8, the inductance of the resonant circuit 10 becomes maximum. Changing the inductance of the resonant circuit 10 leads to parametric excitation of electromagnetic waves. When the inductance changes with a frequency two times greater than the resonance frequency f _{0 of the} oscillations of circuit 10, powerful oscillations arise in the resonant circuit 10 with a voltage on the inductance coil 8 of circuit 10 of more than 10 kV. In conductors and inductors 8 of the resonant circuit 10, there are chaotic fluctuations of electrons, the energy and amplitude of which are proportional to the ambient temperature. As theory and experience show, in the resonant circuit 10 disordered, constantly changing their direction, frequency and magnitude very weak fluctuation currents of magnitude less than 10 ^-12 A induced by the heat of the environment, the Earth’s magnetic field, atmospheric discharges, electrical devices, and radio waves constantly circulate. A parametric resonant generator amplifies these electrical vibrations, which leads to an increase in power in the circuit.

When changing the inductance of the resonant circuit 10 to ΔL, the total inductance of the resonant circuit 5 changes from L ₁ + L ₂ to L ₁ + L ₂ -ΔL. If the frequency f changes in parameters of the resonant circuit 10 to 2 times the resonance frequency f ₀ contour is amplified oscillation energy and the voltage across the inductor 8. Tesla transformer 12 amplifies the electric voltage fluctuations, and transmits them to the step-down transformer 15 Tesla with a resonance frequency f ₀ . The electric energy from the Tesla transformer 15 is transferred to the rectifier 16, converted in frequency to the inverter 17 and transferred to the load 18. The frequency f is changed by adjusting the speed of the rotor 4 of the electric machine 1 using the frequency converter 19. The stator housing 3 is made of insulating or ferromagnetic material that ensures the operability of a parametric resonant generator at a resonant frequency of up to 10 kHz.

In the proposed parametric resonant generator, the load 18 is separated from the resonant circuit 10 by inserting a direct current in the form of a rectifier 16, so the change in load 18 does not affect the parameters of the parametric generator.

An example of a parametric resonant generator.

A parametric resonant generator is made with a vertical axis of the rotors 4. Each inductor 8 has 6 turns of insulated copper wire wound around the tooth 7 in grooves 6 of the stator 3 with an inner diameter of the stator of 3,900 mm and a stator length of 3,100 mm. The rotor diameter is 4 850 mm, the rotor length is 4 100 mm. The number of projections 20 on the rotor 4 is 40, the number of inductors 8 on the stator 80. The rotor speed of 4,000 rpm.

When the rotor 4 rotates, the protrusions 20 periodically coincide with the dimensions of two adjacent inductors 8. Each inductance 8 has an additional winding 11 with the number of turns 12 to form the secondary winding of the Tesla transformer 10.

All inductors 8 of stator 3 in each parametric resonant electric machine 1 and 2 are interconnected in series with the formation of the primary winding 13 of the Tesla transformer 12 and with a capacity of 9 with the formation of the resonant circuit 10 with a resonant frequency f ₀ = 1 kHz. All additional windings 11 of the inductors 8 are interconnected in series and form the secondary winding 14 of the Tesla transformer 12.

Tesla 15 step-down transformer is made similarly.

The voltage at the input of the Tesla 12 transformer is 10 kV, the rectified voltage at the rectifier is 16 500 V, the voltage at the three-phase inverter is 17 230/380 V, the frequency is 50 Hz, and the electric power is 12 kW.

The parametric resonant generator has a simple design, high power when the load changes, is resistant to short circuits and can be used to power radio stations, in welding technologies, and also as a compact high-frequency power source.

Claims (6)

1. A parametric resonant generator containing a group of coils connected in series and forming a resonant circuit and a device for periodically changing the inductance of the resonant circuit mounted on the axis of the electric motor, characterized in that the parametric resonant generator and the device for periodically changing the inductance of the resonant circuit are made of the first and second parametric resonant electric machines mounted on top of each other, each of the electric machines has a the ator and rotor, the rotors of two electric machines are mounted on a common shaft, in the grooves of the stator of the first and second electric machines around the stator teeth are installed the main inductors, which are connected to each other and to the capacitance in a separate resonant circuit of each electric machine, each main inductor in the second electric machine has an additional winding, all additional windings of all inductors of the second electric machine are connected in series and together with the main coils and inductances are made in the form of a Tesla resonant transformer, in which the main inductors of the resonant circuit are the primary winding, and the additional windings of the inductors are made in the form of a secondary winding, the terminals of the secondary winding of the Tesla transformer are connected through a rectifier or another Tesla transformer, a rectifier and an inverter with a load and through a frequency converter with a resonant circuit of the inductors of the first electric machine, the rotors of the first and second electric machines in operechnom section have on the external rim of protrusions and grooves of the rotor projection dimensions equal to the total size of two teeth and two stator slots, the rotor and the number of projections is less than twice the number of stator teeth in each electric car. 2. The parametric resonant generator according to claim 1, characterized in that the stators and rotors of the first and second parametric resonant electric machines are made of ferromagnetic material, in which the coil inductance is independent of the current in the coil in the frequency range 0-10 kHz, for example, ferrite . 3. The parametric resonant generator according to claim 1, characterized in that the stators of the first and second parametric resonant electric machines are made of insulating material, such as fiberglass. 4. The parametric resonant generator according to claim 1, characterized in that the rotors of the first and second parametric resonant electric machines are made of non-magnetic material, such as titanium or aluminum alloy. 5. The parametric resonant generator according to claim 1, characterized in that the rotors of the first and second parametric resonant electric machines are made of insulating material, such as fiberglass, and the rims of the rotors with grooves and protrusions are made of ferromagnetic material. 6. A method of exciting electric oscillations in a parametric resonant generator by periodically changing the magnetic field energy and inductance of the inductance coils of the resonant circuit with a frequency twice the frequency of the resonant circuit, characterized in that the rotors are mounted on a common axis-parallel parametric resonant electric machines the shaft, in the grooves of the stator of the first and second electric machines around the stator teeth set the main inductor, connecting They are connected in series with the capacitance and form a resonant circuit in each electric machine, additional windings are installed on the main inductors in the second electric machine, connected in series so that the main and additional windings of the inductors of the second electric machine form the primary and secondary windings of the Tesla resonant transformer , the terminals of the secondary winding of the Tesla transformer are connected through a rectifier or another Tesla transformer, a rectifier, an inverter with a load and through a frequency converter with a resonant circuit of the first electric machine, in the rotors of the first and second electric machines on the outer rim, alternating protrusions and grooves are performed in an amount half as many as the number of teeth and grooves of the stator, fed from the network through the frequency converter to the resonant circuit the first electric machine voltage with a frequency f twice the resonant frequency f _{0 of the} resonant circuit, and use the first electric machine as a parametric resonant ele of the motor, when the rotors of the first and second electric machines rotate, the protrusions of the rotor periodically overlap the grooves and stator teeth, change the magnetic field of the main stator coils and the inductance of the resonant circuit with a frequency f twice the resonant frequency f _{0 of the} resonant circuit, parametrically excite electromagnetic oscillations in the resonant the circuit of the second electric machine, the oscillations amplify the voltage in the Tesla resonant transformer, lower the voltage in another Tesla transformer, straightening lyayut rectifier is converted in frequency and voltage in the inverter and supplied to the load through the inverter and the input of the resonant circuit of the first electrical machine.

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