ES2950176B2 - Generator for the production of electrical energy - Google Patents

Description

DESCRIPTION

Generator for the production of electrical energy

The present invention relates to electrical power engineering and can be used in power supply systems of different sectors of the national economy: industrial, agricultural, defense, transportation and service facilities.

The prior art describes a device for the production of electrical energy according to the RU 2261521 standard (published on September 27, 2005) which consists of a source of electrical energy that feeds a current pulse generator whose output is connected to a capacitor of energy storage and a discharger connected in series to the primary winding of a transformer, whose high-voltage secondary winding and a capacitor connected in parallel form a resonant circuit, which with the use of a diode establishes a positive feedback with the storage capacitor of the transformer. discharger, and the tertiary winding of the transformer feeds the load through a bridge rectifier.

A disadvantage of such an electrical energy generator is that, over time, due to the formation of oxide and partial mechanical disintegration of the electrodes of the arrester, a change in the discharge frequency of the arrester is observed, which initiates oscillations in the tertiary winding circuit of the transformer. The disintegration process of the discharger electrodes is due to the presence of plasma between the electrodes that causes disintegration by electrical erosion of the metal of the electrode, which inevitably results in an increase in the distance between them in relation to the initial distance and a shift in the frequency spectrum of the arrester oscillations relative to the resonant frequency of the primary winding circuit of the transformer. Therefore, the spectral density of the discharge current at the resonant frequency of the primary winding circuit of the transformer decreases, which can lead to outage of the device. The shift in the frequency spectrum of the arrester can also be determined by a change in the air conditions in the discharge space. It is well known that the discharge repetition rate increases as the humidity of the air increases (publication by Pengfei Xu, Bo Zhang, Shuiming Chen and Jinliang He, "Influence of humidity on the characteristics of positive corona discharge in air", Physics of Plasmas 23, 063511 (2016);

The technical result of the present invention lies in the improvement of the reliability and consistency of the operation of the generator to produce electrical energy.

The technical result is achieved in the generator for the production of electrical energy, designed with the possibility of connection to the starting and disconnection of the electrical energy source, whose output is connected, through the rectifier, to the energy storage capacitor. of the arrester unit connected in series to the primary winding of the transformer, whose high-voltage secondary winding together with the capacitor connected in parallel form a resonant circuit that establishes positive feedback with the energy storage capacitor of the arrester unit, and the tertiary winding of the transformer feeds the load through the rectifier, in which the arrester unit is implemented as several arresters connected in parallel and characterized by different breakdown voltage values and by frequency spectra shifted relative to each other, but overlapping, wherein the energy storage capacitor comprises several capacitors, each of which is connected to a respective arrester of the arrester unit. Also, the number of dischargers is equal to the number of storage capacitors and rectifiers connected to them, through which they are charged from the starting source or from the positive feedback circuit.

When several arresters connected in parallel are used, and characterized by different values of breakdown voltage and by frequency spectra displaced in relation to each other, but overlapping, the spectral densities of the arresters are added to the resonance frequency of the arrester circuit. primary winding of the transformer and, with a shift in the frequency spectrum of oscillations of the first arrester relative to the resonant frequency of the primary winding circuit of the transformer (for example, due to an increase in the distances between the electrodes in the with the passage of time or the change in air conditions in the discharge space) an increase in the cumulative spectral density is guaranteed due to a contribution of the spectral density of another or other arresters whose spectra overlap with the spectrum of the first arrester. Therefore, the technical result is achieved in terms of improved reliability and stability of operation of the device for generating electrical power in the case of a shift in the frequency spectrum of the arrester due to a change in distance between the electrodes or the air conditions in the discharge space.

In a preferred embodiment, the arresters of the arrester unit have shifts in the frequency spectra ensuring a cumulative spectral density close to uniformity over the frequency range of the arrester.

In a preferred embodiment, the primary winding circuit of the transformer is in the form of a flat coil with a resonant frequency of 2.45 MHz.

In a preferred embodiment, the rectifier is in the form of a diode bridge.

In a preferred embodiment, the arresters have frequency spectrum shifts of 1-20 kHz relative to each other.

The operating principle of the generator for the production of electrical energy is explained in Figure 1 which shows its block flow diagram.

The generator for the production of electrical energy is implemented in a generator connected to the source (1) of starting electrical energy, the output of which is connected to a charge storage capacitor executed from capacitors (2.1, 2.2, 2.3) of the unit arrester (3), connected in series to the primary winding (4) of the transformer (5), which together with the capacitor (6) connected in parallel form a resonant circuit, and whose high-voltage secondary winding (7) together with the capacitor (8) connected in parallel form a resonant circuit with the positive feedback unit (9) of this circuit through the rectifiers (17, 18, 19) with the capacitors (2.1, 2.2, 2.3) of the arrester unit (3), in which the tertiary winding (10) of the transformer (5) together with the capacitor (11) connected in parallel form a resonant circuit and feed the load (13) through the rectifier (12), executed according to the diode bridge scheme, in which the arrester unit (3) comprises a first arrester (14), a second arrester (15) and a third arrester (16) connected in parallel, and characterized by different breakdown voltage values and by frequency spectra displaced in relation to each other by 10 kHz, but overlapping. Oscillations in the circuits formed in the primary, secondary and tertiary windings are initiated using a starting source. Then, due to positive feedback, they are transmitted to the storage capacitors, which charge and, after discharging the dischargers, initiate oscillations in the primary winding circuit, which excite oscillations in the secondary and tertiary windings. Due to the positive feedback and the conversion of the rectifiers 17, 18, 19 of the alternating voltage of the secondary winding to a constant, the constant voltage charges the storage capacitors and the process repeats. Afterwards, the boot source can be turned off. The accumulation of energy for the continuation of the process and obtaining energy in the charge is carried out by multiplying the number of electrons in the gaps of the dischargers during the ionization of air molecules due to their collision with the electrons of the streamers that arise during

The generator for the production of electrical energy works in the following way.

The source (1) of starting electrical energy serves to start the generator for the production of electrical energy, and is used only at the initial moment and includes the source of electrical energy, the electrical network, an accumulator or a battery being able to be used in This capacity, a low voltage converter into high voltage, from which voltage is applied to the capacitors (2.1, 2.2, 2.3) through diodes, and through the first arrester (14), the second arrester (15) and the third arrester (16) of the arrester unit (3) to the primary winding (4) of the transformer (5), which together with the capacitor (6) connected in parallel form a resonant circuit. The electrical charges accumulated by the capacitors (2.1, 2.2, 2.3) from the source (1) of starting electrical energy are applied to the primary winding (4) of the transformer (5) through the first arrester (14), the second arrester (15) and the third arrester (16) of the arrester unit (3), thereby establishing a magnetic field with a high spatial tension gradient in the surrounding space. At this time, initial corona discharge discharges are formed in the first discharger (14), the second discharger (15) and the third discharger (16) of the discharger unit (3) due to the impact ionization by electrons of air molecules and the generation of avalanche electron flows near the target anode tip due to the highly non-uniform field. The ions of the air molecules, having much more mass, do not reach the cathode at the time of the discharge pulse and form a massive charge near the cathode that interrupts the corona discharge pulse and slowly dissipates into the surrounding space or It recombines with electrons flowing into the discharge space from the cathode. Photoionization of air molecules, which occurs due to the action of ultraviolet radiation of the initial discharges on them, is also of great importance for the development of avalanche. Therefore, current pulses are generated in the discharger unit (3), a current that is higher than the electron current that initiates the corona discharge.

At the end of the discharge in the discharge unit (3), the magnetic field of the primary winding (4) is transmitted by induction to the secondary winding (7) of the transformer (5), which together with the capacitor (8) form a circuit resonant. The voltage of the secondary winding (7) of the transformer (5) is transmitted to the capacitors (2.1, 2.2. 2.3) through the positive feedback unit (9) and the rectifiers (17, 18, 19), thus realizing the positive feedback. After the time necessary for the generator to oscillate, the starting electrical power source (1) is turned off.

In a period of time that is characteristic of each arrester of the arrester unit (3), the electrical charge accumulated by the capacitors (2.1, 2.2, 2.3) is fed, when discharged, to the primary winding (4) of the transformer ( 5), around which a pulsed magnetic field with increased energy is generated due to the formation of initial discharges of the corona discharge. In addition, due to induction, energy is fed to the secondary winding (7) of the transformer (5), forming a resonant circuit together with the capacitor (8). The excess energy obtained is eliminated by the tertiary winding (10) of the transformer (5) which forms a resonant circuit together with the capacitor (11), and feeds the load (13) through the rectifier (12), executed according to the diode bridge scheme.

Suppose that the maximum spectral density of the frequency spectrum of the first arrester (14) originally coincides with the resonance frequency of the circuit formed by the primary winding (4) of the transformer (5), in which the maximum spectral density of the second arrester (15) and the third arrester (16) are located on both sides of the maximum spectral density of the frequency spectrum of the first arrester (14). Then, in the case of a shift of the maximum spectral density of the frequency spectrum of the first arrester (14), for example, in the direction of the maximum spectral density of the frequency spectrum of the second arrester (15), a shift that must be to a change in the distance between the electrodes of the first discharger (14), the second discharger (15) and the third discharger (16) or to a change in the air conditions in the discharge space, the spectral density of the first discharger ( 14) at the resonant frequency of the primary winding circuit (4) of the transformer (5) will decrease, however, the spectral density of the frequency spectrum of the third arrester (16) will increase at that time. In the case of a shift of the maximum spectral density of the frequency spectrum of the first arrester (14) in the direction of the maximum spectral density of the frequency spectrum of the third arrester (16), the spectral density of the first arrester (14) a The resonance frequency of the primary winding circuit (4) of the transformer (5) will decrease, however, the spectral density of the frequency spectrum of the second arrester (15) will increase at that time, compensating for the decrease in the spectral density of the spectrum of frequency of the first arrester (14). That is, the use of several arresters, first arrester (14), second arrester (15), and third arrester (16), executed with a shift in the maximum spectral density of the frequency spectrum in relation to each other, when their spectra overlap, it will guarantee greater reliability and consistency of the operation of the generator for the production of electrical energy by compensating for the decrease in spectral density of the first arrester (14) at the resonance frequency of the primary winding circuit (4) through the increase of the spectral density of the second arrester (15) or the third arrester (16) of the arrester unit (3).

Stabilization of the amplitude of the spectral density of the arresters at the resonant frequency of the primary winding circuit (4) of the transformer (5) for two or more arresters of the arrester unit (3) is carried out in a similar way.

Therefore, when several arresters connected in parallel are used, characterized by different values of breakdown voltage and by frequency spectra displaced in relation to each other, but overlapping, the spectral densities of the arresters are added to the resonance frequency of the arrester. primary winding circuit (4) of the transformer (5) and, with a shift in the frequency spectrum of the oscillations of the first arrester (14) in relation to the resonance frequency of the primary winding circuit (4) of the transformer (for For example, due to the increase in the distance between the electrodes over time or the change in air conditions in the discharge space) an increase in the cumulative spectral density is guaranteed due to the contribution of the spectral density of another or other dischargers, whose spectra overlap with the spectrum of the first arrester (14). Therefore, in the described generator for the production of electrical energy, the achievement of the technical result is guaranteed in the form of greater reliability and consistency of operation of the generator for the production of electrical energy. In this case, the technical result will be achieved for two or more arresters, and the number of arresters is equal to the number of storage capacitors and rectifiers connected to them, through which these capacitors are charged from the starting source or from the positive feedback loop.

Claims (1)

Generator for the production of electrical energy, designed with the possibility of connection to a source (1) of starting electrical energy and disconnection thereof, in which the output of the source is connected, through a rectifier, to a capacitor energy storage of a discharger unit (3) that is connected in series to a primary winding (4) of a transformer (5), whose high-voltage secondary winding (7) together with a capacitor (8) connected in parallel They form a resonant circuit that establishes positive feedback, through a rectifier, with the energy storage capacitor of the discharger unit (3), and a tertiary winding (10) of the transformer (5) supplies a load (13). through a rectifier (12), characterized in that the arrester unit (3) is executed as several arresters (14, 15, 16) connected in parallel, and characterized by different breakdown voltage values and by shifted frequency spectra one in relation to the other, but overlapping, in which the energy storage capacitor comprises several capacitors (2.1, 2.2, 2.3), each of which is connected to a respective discharger (14, 15, 16) and to the rectifier (17, 18, 19) of the unloader unit (3). Generator for the production of electrical energy according to claim 1, characterized in that the arresters of the arrester unit (3) are executed with shifts in the frequency spectra guaranteeing a cumulative spectral density close to uniformity in the frequency range of the arresters. . Generator for the production of electrical energy according to claim 1, characterized in that the primary winding (4) of the transformer (5) is executed as a flat coil with a circuit resonance frequency of 2.45 MHz. Generator for the production of electrical energy according to claim 1, characterized in that the rectifier (12) of the tertiary winding (10) is executed as a diode bridge. 5. Generator for the production of electrical energy according to claim 1, characterized in that the arresters of the arrester unit (3) are executed with shifts in the frequency spectrum of 1-20 kHz relative to each other.