RU116973U1 - DEVICE FOR PRODUCING ENERGY FROM SMOKE GASES - Google Patents

Abstract

1. A device for obtaining energy from flue gases, containing a gas reactor with a pumping source and a branch pipe for supplying gas to the reactor cavity, and the reactor pumping source contains an electromagnetic wave generator with a resonator and a high-voltage spark gap, the electrodes of which are brought out into the reactor cavity, characterized in that it additionally contains a converter of the reactor plasma energy into electrical energy, the reactor vessel is made of a refractory dielectric material and is installed in the resonator of the electromagnetic wave generator, while the inlet pipe for supplying gas to the chamber cavity is equipped with a check valve, the reactor plasma energy converter into electrical energy is made in the form nozzle with inductive winding and is installed at the outlet of the reactor, and the inductive winding of the nozzle is connected to the supply input of the pumping source and to the output of the device. ! 2. The device according to claim 1, characterized in that the refractory dielectric material of the reactor vessel is made of porcelain and / or ceramics. ! 3. The device according to claim 1, characterized in that the refractory electrodes are made of tungsten or graphite. ! 4. The device according to claim 1, characterized in that the pump source is pulsed, and the frequency of its electromagnetic waves and / or discharge pulses is selected equal to one or more resonant frequencies of absorption of molecules and atoms of flue gases.

Description

The utility model relates to energy, specifically to devices for generating energy from flue gases.

A device is known for generating energy from flue gases (SU 1824510, IPC: F23L 15/00, 1993), comprising a heat exchanger installed in the chimney of a thermal power plant (CHP) and connected at the outlet to the turbine of the CHP.

A disadvantage of the known device for generating energy from gas waste is the lack of conversion of flue gas energy into electrical energy associated with the selection of only part of the heat from the flue gas. Another disadvantage of the known device is the lack of environmental friendliness. This is due to the fact that the flue gases of CHP plants, which are the main source of atmospheric pollution, contain, according to GOST 17.2.1.04-77 (RU), carbon dioxide (С0 ₂ ) - 93% and 7% - the rest in decreasing order: sulfur dioxide, nitrogen oxides, carbon monoxide, as well as soot, dust particles, often radioactive elements. At the same time, carbon dioxide (C0 ₂ ), which makes up the main percentage of flue gases, passes through the known device almost without delay and pollutes the atmosphere, causing a greenhouse effect in it.

These disadvantages are eliminated in a device for generating energy from air gases (US 69369761, NKI: 315.111.91; 315.108, 2005), containing a gas reactor with a pump source and a pipe for supplying gas to the reactor cavity, and the reactor pump source contains electromagnetic waves generator with a resonator and a high voltage arrester, the electrodes of which are brought into the cavity of the reactor. In this case, the internal cavity of the reactor is connected through a sealed pipe (waveguide) to the output of the electromagnetic wave generator. The reactor vessel is made of quartz glass with double walls and nozzles for connecting the cavity between the walls with a heat exchanger. The space between the walls is filled with a coolant, mainly water, heated by the radiation of a gas plasma generated in the chamber cavity. Heated coolant can be used to produce mechanical and / or electrical energy using steam turbines.

The disadvantages of this device are: a relatively small output power associated with insufficient strength of the quartz chamber; the difficulty of operational control of the output power of a gas reactor, associated with the instability and relatively large required time of formation of the "energy core" of the plasma in an insufficiently strong glass vessel; as well as relatively large dimensions, due to restrictions on the strength of the reactor vessel (on the specific energy of pressure on the walls of a glass vessel in the reaction zone).

An object of the invention is to eliminate the disadvantages of the prototype and, first of all, increasing the output power of the device, the ability to control its energy in real time.

The technical result that provides the solution to this problem is the pulse activation of the gas reagent and the adjustment of the average output power of the device by the frequency of the activation pulses.

The achievement of the claimed technical result and, as a result, the solution of the technical problem is achieved by the fact that the device for generating energy from flue gases, containing a gas reactor with a pump source and a pipe for supplying gas to the cavity of the reactor, and the pump source of the reactor contains an electromagnetic wave generator with a resonator and a high voltage arrester, the electrodes of which are brought into the cavity of the reactor, according to a utility model, it further comprises a converter of plasma energy of the reactor into electric tritic energy, the reactor vessel is made of refractory dielectric material and is installed in the resonator of the electromagnetic wave generator, while the inlet for supplying gas to the chamber cavity is equipped with a check valve, the plasma energy of the reactor into electrical energy is made in the form of a nozzle with an inductive winding and is installed at the output reactor, and the inductive winding of the nozzle is connected to the supply input of the pump source and to the output of the device. In this case, the refractory dielectric material of the camera body is made of porcelain or ceramic. Refractory electrodes are made of tungsten or graphite. The pump source is pulsed, and the frequency of its electromagnetic waves and / or discharge pulses is chosen equal to one or more resonant frequencies of absorption of molecules and atoms of flue gases. The execution of the reactor vessel from refractory dielectric material and its installation in the magnetron resonator allows the electromagnetic pumping of the gas reagent through the radiolucent gas reactor vessel in the longer wavelength region of the spectrum of resonant frequencies of absorption of electromagnetic waves (EMW). This makes it possible to use powerful magnetrons and klystrons with high efficiency for pumping in comparison with short-wave EMW sources and at the same time simplify the design of the device as a whole.

The introduction of a plasma energy converter of the reactor into electrical energy, made in the form of a nozzle with an inductive winding and installed at the outlet of the reactor, allows you to directly convert the plasma energy of the utilized gases into electrical energy. The connection of the inductive winding of the nozzle with the supply input of the pump source and with the output of the device allows you to provide your own needs with electricity for initiating the combustion reaction of flue gases and powering external energy consumers.

The execution of the pump source pulsed, the choice of the frequency of its electromagnetic waves and / or discharge pulses equal to one or more resonant frequencies of absorption of molecules and flue gas atoms, as well as limiting the relaxation of the plasma by shielding the reaction zone from an external neutral medium, can reduce the energy consumption for activating the avalanche chemical reaction and at the same time increase the output energy of a gas reactor.

Figure 1 shows the design of the device for generating energy from flue gases, figure 2 - its cross section.

A device for generating energy from flue gases comprises a gas reactor 1 with a pumping source 2, a pipe 3 for supplying gas to the cavity of the reactor 1, and a nozzle 4 for removing plasma from the reaction zone. The pump source 2 of the reactor 1 contains an electromagnetic wave generator, for example, a magnetron 5 and a high voltage arrester 6, the electrodes 7 of which are brought into the cavity of the reactor, and the modulating output 8 is connected to the cathode 9 of the magnetron 5. The output of the electromagnetic waves (EMW) of the magnetron 5 is connected by the waveguide 10 to the resonator 11, through the cavity of which the gas reactor 1 passes. The reactor vessel 1 is made of a cylindrical shape from a refractory dielectric (radiolucent) material, for example, from porcelain and / or ceramic. An inlet pipe 3 for supplying a gas reagent is installed on one of the end sides of the reactor 1, and a nozzle 4 is installed on the other end side. The pipe 3 is equipped with a check valve 12, and the nozzle 4 is equipped with an inductive winding 13, forming an electric energy source 14 connected to the supply input 2 pump sources and with external consumers of electricity. The high-voltage spark gap 6 is made in the form of an inductive or capacitive energy storage with an adjustable pulse repetition rate of 5 pulses modulating the magnetron and bursts of discharge pulses supplied to the electrodes 7. The frequency f _{M of} high-frequency electromagnetic waves in each magnetron pulse 5 and the frequency f _{H of the} discharge pulses in the packet are selected one or more resonant frequencies f ₀ (Fraunhofer lines) of absorption (JOURNAL OF RESEARCH of the National Bureau of Standards Phusises and Chemistry. Vo1.67A, 3, May-June, 1963; Yamanov D.N. Fundamentals of electrodynamics and p radio wave propagation - Part 2: Fundamentals of electrodynamics - Lecture texts - M: MGTU GA, 2005. 100 c) electromagnetic waves with flue gas (C0 ₂ - reagent and its impurities) introduced into the cavity of the reactor 1. Volume of the internal cavity (chamber) of the gas the reactor 1 is selected from the condition that the energy of the pump source 1 is sufficient for the resonant activation of the flue gas and exclude the rupture of the chamber 1 during the explosion of the mass of the gas reagent enclosed in it.

A device for generating energy from flue gases works as follows. The energy storage device 6 is supplied with a supply voltage U ₀ . At the same time, flue gases fill the cavity of the gas reactor 1 through the valve 12, which is open in the normal state. When the high-voltage spark gap 6 enters the operating mode, the latter with a follow-up period T gives high-voltage modulation pulses of negative polarity and a duration of τ to the cathode 9 of the magnetron 5. Simultaneously with the same follow-up period 7 to the electrodes of the gas discharge reactor are given burst pulse duration τ c and the frequency f _H of the pump corresponding to or a multiple of the resonance frequency f ₀ of the gas absorption pear ta. Under the influence of a potential difference> 30 kV / cm between the electrodes 7 of the gas reactor 1, an electrical breakdown of the gas reagent and the formation of a streamer - paths from current carriers (ions and electrons) with a charge density of the order of 10 ~ ⁷ cm ^{-3 occur} . At the same time, the magnetron 5, under the influence of high-voltage pump pulses, generates packs of high-frequency electromagnetic pump waves (EMW) with a frequency of f _m = f ₀ and with an energy density of at least 1 J / cm ² and transmits them through waveguide 10 to resonator 11 for electromagnetic pumping of an ionized gas reagent in the chamber of a gas reactor 1. At the same time, due to the resonant absorption of EMW energy and impact ionization, molecular bonds and С0 ₂ molecules are broken into constituent elements

Where:

C = (Ce) is a neutral carbon atom having one bond electron for each atom in the carbon chain of the fuel;

0 ₂ = (OeO) ~ an oxygen molecule having one bonding electron between two atoms of the molecule;

S., Oh. - negative carbon and oxygen ions, respectively;

0+ is a positive ion.

The electrodynamic interaction of C. and 0+ ions causes a combustion reaction (carbon oxidation) with the formation of carbon monoxide and heat Qi

The formation of CO, which is unstable to “streamer” ionization, emitted heat Q, and the resonant action of EMW energy and the electric discharge of pump source 2 on the ionized medium, which is unstable to “streamer” ionization, contribute to the development of a further ionization process and the destruction of oxygen atoms and ions with the formation of their mass deficit TT1 . An increase in the density of charge carriers in the reactor 1 to 10 ¹⁴ cm " ³ leads to the initiation of" oxygen reactions "

accompanied by explosive destruction of oxygen molecules, the release of a free electron of their bond and quantum energy Q _{2 of} secondary ionizing radiation from the ultraviolet to the soft X-ray range of electromagnetic waves, leading to avalanche ionization of the gas reagent in reactor 1 and to the complete separation of electrons from positively charged nuclei of oxygen atoms and other components of flue gases. The presence in the flue gases of a small percentage of nitrogen, which binds a part of the oxygen in the reactor 1, slightly reduces the reaction rate (5) due to the fact that nitrogen molecules, having a negative excess charge, surround part of the oxygen molecules having a positive excess charge, forming oxygen aggregates screened by nitrogen from ionizing effects. If the primary (from the pumping source 2) and / or secondary (the result of the “oxygen reaction”) ionizing effect is sufficient to destroy nitrogen, the molecule of which is twice as strong as the oxygen molecule, since it has not one, but two binding electrons, then nitrogen collapses not only into atoms, but also fragments representing other chemical elements in the nitrogen reaction

The positively charged nuclei of the atoms of the reacted gases freed from electron shells are combined (due to freedom of movement and the possibility of approaching the boundary of the action of powerful gravitational forces) into a common positive nucleus 15 and an electron cloud 16 above the combined nucleus 14. In Mills (www.blacklighpover.com) R.L. (USA) the combination of nuclei and an abrupt increase in the energy of a gas plasma are explained by the tunneling effect, in the works (www.chukanovenergy.com) Chukanova KB (Bulgaria) - previously unknown from classical physics laws of the material world. In this case, due to the difficulty of access of neutral atoms to the reaction zone from the external environment (the predominance of the ionization process over the relaxation process) and the combination of nuclei into one common mass, the electrons jump at high energy levels relative to the nuclei distant from them. During the transition of excited electrons to lower energy orbits, quantum energy is released, which additionally causes instantaneous heating of the gas reagent in chamber 1 and energy is released through nozzle 4 mainly in the form of kinetic plasma energy. The plasma passing through the cavity of the nozzle 4 induces a pulsed electric current in the inductive winding 13, which is supplied to the drive 2 to be converted into a shape suitable for powering the magnetron 5 and spark gap 6, as well as for powering external consumers of electricity. After the plasma leaves the chamber 1, a vacuum vacuum is formed in its cavity. The formation of vacuum leads to tearing off the check valve 12 and the intake of the next batch of gas reagent through the pipe 3 into the cavity of the reactor 1. Next, the pulse mode of operation of the gas reactor is repeated. The output power of the electric energy of the device for receiving energy from gas waste is regulated by the repetition rate of the pump pulses of device 2 (not shown in the figures).

The specified utility model is not limited to the above example of its implementation. Within the framework of this utility model, the activation of a gas reagent is possible with various combinations of parameters and types of sources of electromagnetic waves and a gas medium. So, to reduce the energy cost of exciting a gas reagent, catalysts can be used. Electron sources can be magnetrons, klystrons, and other sources of electromagnetic waves, the emission spectrum of which coincides with the absorption lines of molecules and atoms of the gas reagent and freely passes through the radiolucent reactor vessel 1. Non-combustible normal Gases sulfur dioxide, nitrogen oxides, carbon monoxide, as well as soot and dust particles in water vapor.

The utility model was developed at the level of technical proposal and physical modeling of the activation of a gaseous medium by the combined action of microwave radiation and electric discharge in a volume isolated from the external environment.

Claims (4)

1. A device for generating energy from flue gases, containing a gas reactor with a pump source and a pipe for supplying gas to the reactor cavity, and the pump source of the reactor contains an electromagnetic wave generator with a resonator and a high voltage arrester, the electrodes of which are brought into the reactor cavity, characterized in that it additionally contains a converter of plasma energy of the reactor into electrical energy, the reactor vessel is made of refractory dielectric material and is installed in the resonator of the generator electromagnetic waves, while the inlet for supplying gas to the chamber cavity is equipped with a check valve, the converter of plasma energy of the reactor into electrical energy is made in the form of a nozzle with an inductive winding and is installed at the outlet of the reactor, and the inductive winding of the nozzle is connected to the supply input of the pump source and to the output devices. 2. The device according to claim 1, characterized in that the refractory dielectric material of the reactor vessel is made of porcelain and / or ceramic. 3. The device according to claim 1, characterized in that the refractory electrodes are made of tungsten or graphite. 4. The device according to claim 1, characterized in that the pump source is pulsed, and the frequency of its electromagnetic waves and / or discharge pulses is chosen equal to one or more resonant absorption frequencies of molecules and atoms of flue gases.