BG113531A - Plant for treatment of flue gases and for generation of electricity with included quantum incinerator - Google Patents

Abstract

The present invention pertains to a plant for the treatment of flue gases released during the disposal of various types of waste, whereby the released heat is recovered and used for the generation of electric power. Said flue gas treatment plant is also used for the generation of electric power, and combines the following options: generation of electric power in an electrical circuit; generation of electric power in a magnetic circuit; and generation of electric using a steam generator. Each of these options can operate independently as well as in any combination. The design of the quantum incinerator and the control of the processes that take place in it leads to the complete combustion of carbon atoms which are a major constituent of the flue gas. Owing to the high temperature and pressure resulting from the formation and excitation of the quantum object plasmasphere, the achieved flue gas purification rate is around 99%. The amount of electric power obtained depends on the operating mode and design dimensions of the incinerator, and can reach values in the range of 50 to 60 kWh(e).

Description

FLUE GAS CLEANING AND ELECTRICAL ENERGY RECOVERY INSTALLATION INCLUDING A QUANTUM INCINERATOR

FIELD OF ENGINEERING

The invention relates to an installation for the purification of flue gases, which are released during the disposal of waste of a different nature, in which the released heat is utilized to obtain electrical energy.

PRIOR ART

The following documents are known from the prior art, which relate to flue gas cleaning systems including incinerators.

Patent document CN 113464952 A relates to a microwave plasma incinerator which includes a main and an auxiliary plasma furnace, each equipped with a microwave plasma torch. Under the main plasma furnace, a conveyor belt is installed for waste that is burned, and in the auxiliary furnace, pipes are installed to remove the flue gases.

Patent document US 4909164 A discloses a hazardous waste incinerator which uses cyclotron resonance plasma which is generated by introducing vaporized waste material and feed gas into a vacuum chamber which is provided with a magnetic and electromagnetic field source. The plasma is formed as a result of the resonance obtained at the same frequency of electromagnetic radiation and the frequency of movement of electrons in the magnetic field. The strength of the electromagnetic field is adjusted so that ionization of the gases takes place, in which plasma is formed. The system includes a plasma reaction chamber, which is equipped with a source of a magnetic field and a source of electromagnetic radiation.

Patent document RU 2184601 C1 describes a method and a plasma reactor for the purification of combustible, smoke and exhaust gases from engines is an internal combustion, in which unwanted chemical compounds such as CO, СО2 , NO2 and H 2 S are removed. The purification of the gases is carried out in the reaction chamber of the reactor, in which the gas enters at a speed of 100 to 200 m/s. Two electrodes are installed in the reaction chamber, connected to high voltage sources, through which the plasma discharge is formed, and the voltage of the electric field between them is from 20 to 80 kW/cm.

Patent document WO 2010123391 A1 describes an apparatus for the utilization of flue gases, in which ionization and avalanche ionization take place in the working chamber when the flue gases pass through. A temperature higher than the sublimation temperature of carbon is created, in which the disintegration of CO2 molecules into carbon and oxygen atoms takes place, which pass into a second chamber for adiabatic cooling. The residual gases are returned for repurification by mixing with the incoming flue gases, and the resulting solid residue is recovered or disposed of.

TECHNICAL ESSENCE OF THE INVENTION

Flue gases from cogeneration plants contain 93% carbon dioxide and 7% sulfur dioxide, nitrogen oxides, carbon monoxide, soot, dust particles, as well as radioactive elements, which makes them a major source of atmospheric pollution. Carbon dioxide from flue gases passes through the known until now devices without achieving a sufficient degree of purification and utilization of flue gases, which leads to environmental pollution and is the main cause of the greenhouse effect.

The object of the invention is an installation for purifying flue gases and obtaining n«^^ electrical energy, which includes a quantum incinerator, with which to achieve purification of flue gases to a high degree and to implement the utilization of the released energy, which is transformed into electrical energy and is synchronized with the power grid, and the resulting solid residue from the process of cleaning flue gases is in a minimal amount and is used as a material in construction, which achieves a zero-waste ecological technology.

The goal is achieved through an installation for cleaning flue gases and obtaining electrical energy, which includes a quantum incinerator, where a plasmasphere is formed by turning on base magnetrons. The plasmasphere is a quantum object that is continuously maintained and periodically excited in the upper part of the working chamber, in which a working environment with a high core temperature of about 10,000 ⁰ C is provided. instead, the hydrogens fuse into a single quantum nucleus, and the freed electrons arrange themselves into quantum levels, similar to the Fermi levels of an ordinary atom. The resulting macro-object is in the form of a sphere, which is reached with the least amount of energy, because the sphere has a minimum surface area per unit volume. The plasmasphere consists of a 2D quantum core surrounded on all sides by a 3D electron cloud.

The main effect of the invention is due to the construction of the quantum incinerator and the management of the processes that take place in it, which leads to the complete combustion of carbon atoms due to the high temperature and pressure that are achieved during the formation and excitation of the quantum object plasmasphere. The flue gas purification rate is 99%.

Another effect of an installation according to the invention is the application of the quantum incinerator, apart from cleaning flue gases and utilizing the energy that is released in this process to obtain electrical energy. This is carried out through an installation that includes a quantum incinerator, in which a quantum object plasmasphere is formed, associated with an increase in the temperature in the working chamber of the incinerator from 5,000° C to 6,000° C and an increase in pressure to 8-10 atm, at which achieves a 99% degree of flue gas purification. The separated heat accompanying the purification of flue gases is utilized through the proposed installation for obtaining electrical energy, which is synchronized with the electrical transmission network.

The installation, according to the invention, for cleaning flue gases and obtaining electrical energy, combines the following options:

- Obtaining electrical energy by electrical circuit;

- Obtaining electrical energy by magnetic circuit; Obtaining electrical energy through a steam generator.

In each of the listed options, electrical energy is obtained, regardless of whether flue gases or fresh air enter the incinerator inlet, and the options can work independently or in any combination. The electrical energy that is obtained depends on the mode of operation and the structural dimensions of the incinerator. In one particular variant, when the upper part of the working chamber has an internal diameter of about 400 mm, respectively and a height of 400 mm, the amount of electricity obtained can reach values of 50 - 60 kWh.

The installation for cleaning flue gases and obtaining electrical energy, including a quantum incinerator, presented in fig. 1, combines the three mentioned options. It includes a quantum incinerator, which consists of a working chamber, the body of which is made of stainless steel, with a built-in water cooling jacket. In the working chamber of the quantum incinerator, two holes are formed, respectively on the lower base and on the upper base, and in the opening of the lower base of the working chamber of the incinerator, a centrifugal filter is installed, under which a solid residue container is located. In the upper part of the housing of the quantum incinerator, on both sides of the opening symmetrically, two oxyhydrogen burners for a magnetic loop are mounted, each equipped with electric valves for oxyhydrogen gas for electrical excitation of a plasmasphere. A mixing chamber is mounted on the very opening of the upper base of the working chamber, and a fan turbine is mounted in it, and the mixing chamber is equipped with a flue gas inlet on one side, and is connected by means of an unburned flue gas pipeline to the centrifugal filter.

Exciting magnetrons are located symmetrically on both sides of the quantum incinerator housing below the oxyhydrogen burners, and base magnetrons are located below them. The oxyhydrogen generator supplies gas to the oxyhydrogen burners for the magnetic loop through the electric oxyhydrogen gas valves for electrical excitation of the capacitor bank pulse supply, and to the oxyhydrogen burner for the current loop through the oxyhydrogen gas electric valve for the current loop. The oxyhydrogen current loop burner is located below the base magnetrons on the left side of the quantum incinerator housing and is connected to the oxyhydrogen generator, which is connected to one oxyhydrogen magnetic loop burner, which is connected to the other oxyhydrogen magnetic loop burner. The installation includes an electrical distribution unit connected in series with a power supply unit, with a controller connected in parallel on the one hand with a control unit for the base magnetrons and a control unit for the excitation magnetrons, and on the other hand bidirectionally with a controllable rectifier, unidirectionally and an electric collection unit, with a unit for oxyhydrogen valve control, with fan turbine control unit and with oxyhydrogen generator control unit. The controller is bi-directionally connected to an output transformer, which on the one hand through a commutator and capacitor bank is connected to one oxyhydrogen torch for a magnetic loop, and on the other hand is directly connected to the second oxyhydrogen torch for a magnetic loop. The oxyhydrogen generator is connected to the power supply unit and the quantum incinerator is connected to a steam generator which is connected to a steam turbine connected on one side to the housing of the quantum incinerator and on the other to a three-phase electric generator connected to the power collection unit which is unidirectionally connected to controllable rectifier and two-way with the power distribution block. The electrical distribution unit is bidirectionally connected to a controller to which a unidirectional commutator is connected, and the output transformer is connected to the electrical collection unit. The capacitor bank is connected to the controller, which is bidirectionally connected to the controlled rectifier.

The installation for cleaning flue gases, including a quantum incinerator, for obtaining electrical energy on an electrical circuit (fig. 2), includes an electrical distribution unit connected in series with a power supply unit and with a controller, which is connected in parallel on one side with a control unit the base magnetrons and a control unit for the excitation magnetrons, on the other with an electric collection unit, with a control unit for oxyhydrogen valves, with a control unit for a fan turbine and with a control unit for an oxyhydrogen generator. The power collection unit is bidirectionally connected to the power distribution unit, and the oxyhydrogen generator is connected on the one hand to the power supply unit and on the other hand through an electric valve for oxyhydrogen gas for a current loop to the oxyhydrogen burner for a current loop, as well as to the power collection unit. The oxyhydrogen current loop burner is mounted on the left side of the quantum incinerator below the base magnetron.

The installation for cleaning flue gases, including a quantum incinerator, for obtaining electrical energy along a magnetic circuit (fig. 3), consists of an electrical distribution unit connected in series with a power supply unit and with a controller, which is connected in parallel on one side with a unit for control of the base magnetrons and a control unit for the excitation magnetrons, and on the other hand with a controllable rectifier, with an electric collection unit, with a control unit for oxyhydrogen valves, with a control unit for a fan turbine and with a control unit for an oxyhydrogen generator. The power collection unit is connected unidirectionally to the controllable rectifier and bidirectionally to the power distribution unit, and the controller is bidirectionally connected to the output transformer, which on the one hand through a commutator and a capacitor bank is connected to an oxyhydrogen burner for a magnetic circuit, and on the other hand is directly connected to a second oxyhydrogen torch for a magnetic loop. The oxyhydrogen generator is connected on one side to the power supply unit and on the other to one oxyhydrogen magnetic loop burner, which is connected to the second oxyhydrogen magnetic loop burner.

The installation for cleaning flue gases, including a quantum incinerator, for obtaining electrical energy through a steam generator (fig. 4), consists of an electrical distribution unit connected in series with a power supply unit and a controller connected in parallel on one side with a control unit of the basic magnetrons and with a control unit for the excitation magnetrons and on the other hand with an electric collection unit and with a control unit for the fan turbine. The quantum incinerator is connected via the steam generator to a steam turbine connected to the three-phase electric generator, which is connected to the electric collection unit, bidirectionally connected to an electric distribution unit, and the steam turbine is connected to the quantum incinerator.

The advantages provided by the installation according to the invention are:

The operation of the installation does not lead to pollution of the atmosphere and the environment.

By means of the proposed installation, in addition to cleaning flue gases, obtaining electrical energy is ensured by utilizing the heat from the complete combustion of residual carbon pollution.

By means of the installation, electrical energy is obtained independently or in combination of the following processes:

- additional quantum current loop;

- excitation of the quantum object plasmasphere and inductive withdrawal of electrical energy along a magnetic circuit;

- by a turbine driven by a steam generator.

DESCRIPTION OF THE ATTACHED FIGURES

Fig. 1 shows a diagram of the installation for cleaning flue gases and obtaining electrical energy, including a quantum incinerator in which:

Electrical distribution block

Power supply

Controller

Output transformer

Commutator

Capacitor battery 4

Controllable rectifier

Three-phase generator

Electrical collection unit

Control unit for LV valves

Fan turbine control unit 19

LV generator control unit

Base magnetron control unit

Control unit for excitation magnetrons oxyhydrogen generator

Steam generator

Steam turbine

Quantum incinerator

Fan turbine

Basic magnetrons

Exciting magnetrons

Electric valves for oxyhydrogen gas for electrical excitation of the plasmasphere

Electric valve for oxyhydrogen gas for current loop plasmasphere

Pipeline for unburnt flue gases

26.1 and 26.2 Hydrogen oxygen burners for magnetic loop

26.3 Hydrogen oxygen torch for current loop

A working chamber consisting of an upper and a lower part.

Mixing chamber

Centrifugal filter

Container for solid residue

Flue gas inlet

In fig. 2 shows a diagram of a flue gas cleaning installation, including a quantum incinerator and obtaining electrical energy via an electrical loop, in which:

Electrical distribution block

Power supply

Controller

Electrical collection unit

Hydrogen oxyvalve control unit

Fan turbine control unit 19

Hydrogen oxygen generator control unit

Base magnetron control unit

Exciting magnetron control unit

Hydrogen oxygen generator

Quantum incinerator

Electric valve for oxyhydrogen gas for current electric circuit

Plasmasphere .3 Hydrogen oxygen torch for current loop

In fig. 3 shows a diagram of a flue gas cleaning installation, including a quantum incinerator and obtaining electrical energy along a magnetic loop, in which:

Electrical distribution block

Power supply

Controller

Output transformer

Commutator

Capacitor battery

Controllable rectifier

Electrical collection unit

Hydrogen oxyvalve control unit

Fan turbine control unit 19

Hydrogen oxygen generator control unit

Base magnetron control unit

Exciting magnetron control unit

Hydrogen oxygen generator

Quantum incinerator

26.1 Hydrogen oxy-torch for magnetic loop

26.2 Hydrogen oxy-torch for magnetic loop

Fig. 4 shows a diagram of a flue gas cleaning installation, including an incinerator and obtaining electrical energy by means of a steam generator, in which:

Electrical distribution block

Power supply

Controller

Three-phase generator

Power collection unit I

Fan turbine control unit 19

Base magnetron control unit

Exciting magnetron control unit

Oxyborogen generator

Steam generator

Steam turbine

Quantum incinerator

EXEMPLARY IMPLEMENTATION OF THE INVENTION

The principle of operation of the installation for cleaning flue gases and obtaining electrical energy, including a quantum incinerator, is illustrated by means of the elements and devices included in it and the functions they perform.

Initially, in the working chamber 27 of the incinerator 18, the pressure is approximately 1.5 atm, and the temperature is about 600 ⁰ C.

Flue gases enter the mixing chamber 28, as a result of which the revolutions of the fan turbine 19 increase, during which the pressure in the working chamber 27 of the incinerator 18 rises to 8-10 atm.

As the pressure increases, the excitation magnetrons 21 are simultaneously turned on and the electrical valves for oxyhydrogen gas for electrical excitation of the plasmasphere 22 are opened.

The temperature of the plasmasphere rises sharply to a value of 5,000° C- 6,000° C, depending on the operating mode, up to 10,000° C. Under these conditions, the carbon burns and, under pressure, the gases are driven in the direction of the centrifugal filter 29, which passes under certain conditions, residual product and fresh air to an external container. The remaining flue gases, through pipeline 25, enter again into the mixing chamber 28. Exciting magnetrons 21 are switched off. The revolutions of the fan turbine 19 decrease and the pressure in the working chamber 27 decreases to about 2 atm. The base magnetrons 20 continue their operation and are not switched off during the entire operation process. When additional quantities of flue gases are introduced for cleaning, the cycle is repeated.

Excitation of the plasmasphere in the working chamber 27 of the quantum incinerator 18 is carried out by means of:

Exciting magnetrons 21 - located on the periphery of the working chamber 27, immediately above the base magnetrons 20;

Pulses from a capacitor battery 6, controlled gas discharges from the oxyhydrogen generator 15 are used as electrodes;

Pressure increase in the working chamber 27, which is created by the fan turbine 19;

The supply of oxyhydrogen gas - participates in the process of excitation of the plasmasphere and helps to further burn the carbon atoms.

Residual gases - during operation, not all gases can be 100 percent processed, and therefore some of them are returned to the bypass for reprocessing, until the requirements of the centrifugal filter 29 are reached.

The quantum incinerator 18 consists of a working chamber 27 with formed lower and upper parts, and in the upper part the plasmasphere is formed. The body of the working chamber is made of stainless steel with high strength indicators, with a built-in water cooling jacket.

A mixing chamber 28 is installed above the quantum incinerator, into which the flue gases enter and mix with the residual combustion products, which are returned for reprocessing until they are completely burned.

The steam generator 16 is fed by the water cooling jacket built into the housing of the quantum incinerator 18 and creates steam for the steam turbine 17, which in turn drives a three-phase electric generator 8 producing three-phase current.

The commutator 5 is turned on before the supply of oxyhydrogen gas, which, upon contact with the plasmasphere, instantly transfers about 1-2 megawatts of electrical impulse from the capacitor battery.

The controllable rectifier 7 is connected to a synchronizing unit for an electrical network, which is an electrical collection unit 1 and is required for charging a capacitor battery 6.

In the oxyhydrogen generator 15, oxyhydrogen gas is formed, necessary for the oxyhydrogen burners 26.1, 26.2, mounted in the upper part of the incinerator above the base magnetrons 20, located above the excitation magnetrons 21, and the oxyhydrogen burner 26.3 is installed on the left side of the quantum incinerator housing, immediately below the base magnetrons 20.

The oxyhydrogen burners for magnetic loop 26.1, 26.2 and the oxyhydrogen burner for current loop 26.3 supply oxyhydrogen gas in portions, on the one hand performing the role of n^ gas high-voltage electrodes, and on the other hand helping to completely burn the residual gases. The oxyhydrogen burners for a magnetic loop 26.1 and 26.2 are controlled by electric valves for oxyhydrogen gas for electric excitation of the plasmasphere 22 installed to them, and the oxyhydrogen burner for a current loop 26.3 is controlled by an electric valve for oxyhydrogen gas for a current loop 23 installed to it.

Exciting magnetrons 21 serve to excite the plasmasphere electromagnetically, by "piercing" part or all of the electronic layers of the different quantum levels of the plasmasphere.

Base magnetrons 20 maintain the plasmasphere in a continuous working state, and when they are turned off, the processes subside until the work process is completely extinguished.

The centrifugal filter 29 is an electromechanical filter installed on the lower base of the quantum incinerator 18 and its function is to remove the residual product after the combustion of the flue gases in the form of waste ash (graphite) and to release purified air that has passed a certain limit of the pressure of the working environment .

A waste container 30 is located immediately next to the centrifugal filter 29, where residual products that can be used as construction material accumulate.

The fan turbine 19 is installed in the mixing chamber 28 and provides the necessary working pressure in the upper part and the adiabatic process in the lower part of the working chamber 27 of the incinerator. The fan turbine 19 operates continuously in a controllable mode and programmatically changes its pressure at certain intervals, synchronized with the operation of the excitation magnetrons 21 and the base magnetrons 20.

The proposed installation, in addition to flue gas purification, is also used to obtain electrical energy, combining the following options:

Obtaining electrical energy by electrical circuit;

Obtaining electrical energy by magnetic circuit;

Obtaining electrical energy through a steam generator.

Each of the options can work independently, as well as in any combination.

To illustrate the method of obtaining electrical energy, which unites all three mentioned options, the following devices are listed included in the installation presented in fig. 1 :

- power distribution unit 1 - this unit is a synchronized input-output commutator of three-phase electricity. It powers the quantum incinerator 18 and at the same time "radiates" into the external electrical network three-phase energy obtained in the incinerator itself;

power supply unit 2 - here the necessary voltages and currents are produced to power the oxyhydrogen generator 15 and the controller 3, through which the processes in the installation are managed and powered;

controller 3 with a control program that, according to a certain algorithm, manages the work processes in the incinerator;

- output transformer 4, by means of which electricity is extracted along a magnetic loop;

- switch 5, which turns on or off the magnetic circuit for additional energy; capacitor battery 6 - high-voltage capacitors, by means of which a charge of about 1-2 MW or more is transferred to excite the plasmasphere in the working chamber 27 of the quantum incinerator 18;

controllable rectifier 7 - has the main function of charging the capacitor battery 6;

- standard three-phase electric generator 8 for obtaining electrical energy;

- electricity collection unit 9 - here the electricity coming from the three-phase standard generator 8, from the magnetic loop of the output transformer 4 and from the electric loop is collected.

electric oxyhydrogen gas valves for electrical excitation of the plasmasphere 22 mounted on the oxyhydrogen burners for the magnetic loop 26.1 and 26.2 and electric oxyhydrogen gas valve for the current loop 23 mounted on the oxyhydrogen burner for the current loop 26.3, which admit oxyhydrogen gas at certain times of the work process;

in the fan turbine 19, which provides the necessary working pressure in the different phases of the work process;

- control unit of the oxyhydrogen generator 12 - monitors the state of the oxyhydrogen generator 15, if necessary changes the state of the electrolyte, regulates the productivity of oxyhydrogen gas or completely shuts down the production of oxyhydrogen gas;

- block for controlling the base magnetrons 13;

unit for controlling the excitation magnetrons 14;

- oxyhydrogen generator 15 - produces oxyhydrogen gas;

- steam generator 16 - produces steam to drive the steam turbine 17;

steam turbine 17 - drives three-phase electric generator 8; |

- rotary compressor 19 to create a different pressure of the incoming gases.

Obtaining electrical energy along an electrical circuit is presented in Fig. 2. This variant of implementation is due to the fact that the plasmasphere represents at a certain moment the equivalent of a high-voltage spherical capacitor charged to 3,000 - 4,000 V. Through the proposed installation, an opportunity has been created that charge to be transferred to the electro-harvesting unit 9. For this purpose, with the help of an electrical valve for hydrogen oxyhydrogen gas for a current circuit 23, hydrogen oxyhydrogen gas is introduced under pressure, which in the conditions of an air envelope reaches the core of the plasmasphere and transfers a positive high-voltage potential to the electro-harvesting unit 9 .The negative potential is transferred directly from the quantum incinerator housing 18. This additional electricity is processed by inverter circuits into standard three-phase voltage synchronized with the standard transmission power grid.

The production of electrical energy along a magnetic loop is presented in fig. 3. An important property of the plasmasphere is that it is effective only if it is brought to an excited state. One of the methods for this is the so-called electrical excitation, which is carried out with a powerful electrical impulse in the periphery of the plasmasphere and leads to the activation of quantum electrons from the inner layers of the plasmasphere, i.e. those located near the nucleus of the quantum object. Quantum electrons effectively extend the excitation pulse by at least 34 times the time. When the discharge circuit of the capacitor battery 6 does not pass through the quantum object plasmasphere, the discharge time is about 1 millisecond or varies depending on the specific structural elements and charge level. When the discharge current passes through the quantum object, it practically turns into a quantum power amplifier (an additional electric 12

L.

source) which amplifies in amplitude and lengthens in time the real flowing current, in which the quantum excited current is added. This causes the process to take more than 4 milliseconds. This is additional power from the quantum process itself, which is supplied electromagnetically through the output transformer 4 (magnetic loop) to the electric collection unit 9 and further through an inverter circuit a three-phase current is obtained.

The production of electrical energy by means of a steam generator is presented in fig. 4. This variant of obtaining electrical energy is due to the conversion of the energy of the steam generator 16 into the mechanical rotation of a steam turbine 17 driving a three-phase electric generator 8. This energy is collected in the electrical collection unit 9 and is synchronized with the external power supply network.

Claims (4)

1. An installation for cleaning flue gases and obtaining electrical energy, including an incinerator, characterized in that the incinerator (18) is quantum and consists of a working chamber (27), the body of which is made of stainless steel, with a built-in water cooling jacket, with two holes formed, one is on the lower base and the other is on the upper base of the working chamber (27), and a centrifugal filter (29) is installed in the opening of the lower base of the working chamber (27), and under a solid residue container (30) is located on it, and two oxyhydrogen burners (26.1) and (26.2) are installed in the upper part of the quantum incinerator housing (18) on both sides symmetrically of the opening, each equipped with electric valves for oxyhydrogen gas for electrical excitation of a plasmasphere (22), with a mixing chamber (28) with a fan turbine (19) installed in it, the mixing chamber (28) on one on one side it is equipped with a flue gas inlet (31) and on the other it is connected by means of a pipe for unburned flue gases (25) to the centrifugal filter (29), as under the oxyhydrogen burners for a magnetic loop (26.1) and (26.2) in the housing on the quantum incinerator (18), exciting magnetrons (21) and base magnetrons (20) are located symmetrically on both sides, and below them on the left side of the housing of the quantum incinerator (18) an oxyhydrogen burner for a current circuit (26.3) is installed , with an electric valve for oxyhydrogen gas for a current loop (23) mounted on it, connected to a oxyhydrogen generator (15), connected to a oxyhydrogen burner for a magnetic loop (26.1), which is connected to a oxyhydrogen burner for a magnetic loop (26.2), as the installation includes an electrical distribution unit (1) connected in series with a power supply unit (2), with a controller (3) connected in parallel on the one hand with a control unit for the base magnetrons (13) and a control unit for the excitation magnetrons (14) and from other side two-way with controllable rectifier (7), one-way with electric collection unit (9), with oxyhydrogen valve control unit (10), with fan turbine control unit (11) and is oxyhydrogen generator control unit (12) , with the controller (3) being bidirectionally connected to an output transformer (4), which on the one hand through a commutator (5) and a capacitor bank (6) is connected to an oxyhydrogen torch for a magnetic loop (26.1), and on the other hand is connected directly with an oxyhydrogen burner for a magnetic loop (26.2), with the oxyhydrogen generator (15) connected to the power unit (2) and the quantum incinerator (18) connected to a steam generator (16) which is connected to a steam turbine (17) connected on the one hand with the quantum incinerator (18), and on the other with a three-phase electric generator (8) connected to the power collection unit (9), connected unidirectionally to a controllable rectifier (7) and bidirectionally to the power distribution unit (1), which is bidirectionally connected to controller (3), to which a unidirectional commutator (5) is connected, and the output transformer (4) is connected to the power collection unit (9), and the capacitor bank (6) is connected to the controller (3), connected bidirectionally to the controllable rectifier ( 7). 2. Installation for cleaning flue gases, including a quantum incinerator, according to claim 1, for obtaining electrical energy on an electrical loop, characterized in that it includes an electrical distribution unit (1) connected in series with a power supply unit (2) and with a controller (3), which is connected in parallel, on the one hand, with a control unit for the base magnetrons (13) and a control unit for the excitation magnetrons (14), on the other hand, with an electric collection unit (9), with a control unit for oxyhydrogen valves (10 ), with a control unit for a fan turbine (11) and with a control unit for an oxyhydrogen generator (12), with the electric collection unit (9) bidirectionally connected to the electric distribution unit (1), and the oxyhydrogen generator (15) on the one hand is connected to the supply unit (2) and on the other hand through an electric valve for oxyhydrogen gas for a current loop (23) with the oxyhydrogen burner (26.3) and to the electrocollecting unit (9). 3. Installation for cleaning flue gases, including a quantum incinerator, according to claim 1 for obtaining electrical energy along a magnetic loop, characterized in that it includes an electrical distribution unit (1) connected in series with a power supply unit (2) and a controller ( 3), which is connected in parallel on the one hand with a base magnetron control unit (13) and an excitation magnetron control unit (14), on the other hand with a two-way controllable rectifier (7), one-way with an electrocollecting unit (9), with an oxyhydrogen valve control unit (10), with a fan turbine control unit (11) and with an oxyhydrogen generator control unit (12), with the electric collection unit (9) connected unidirectionally to the controllable rectifier (7) and bidirectionally with the electrical distribution unit (1), and the controller (3) is bidirectionally connected to an output transformer (4), which, on the one hand, through a commutator (5) and a capacitor bank (6), is connected to an oxyhydrogen burner for a magnetic circuit (26.2), and on the other hand, it is directly connected to a oxyhydrogen burner for a magnetic loop (26.1), and the oxyhydrogen generator (15) is connected on the one hand to the power supply unit (2), and on the other to an electric valve for oxyhydrogen gas to a current loop (23), mounted on a current loop oxyhydrogen torch (26.3), wherein the magnetic loop oxyhydrogen torch (26.2) is connected to a magnetic loop oxyhydrogen torch (26.1), each having electrical valves for oxyhydrogen gas for electric plasma excitation ( 22). 4. Installation for cleaning flue gases, including a quantum incinerator, according to claim 1 for obtaining electrical energy by means of a steam generator, characterized in that an electrical distribution unit (1) is connected in series with a power supply unit (2) and a controller (3) ), connected in parallel on the one hand with a control unit for the base magnetrons (13) and a control unit for the excitation magnetrons (14) and on the other hand with an electric collection unit (9) and a control unit for the fan turbine (11), as the housing of the quantum incinerator (18) is connected by means of the steam generator (16) to a steam turbine (17) connected to the three-phase electric generator (8) which is connected to the power collection unit (9) bidirectionally connected to the power distribution unit (1) such as the steam the turbine (17) is in turn connected to the quantum incinerator (18).