RU155193U1 - MAGNETIC ELECTRIC CURRENT GENERATOR - Google Patents

Abstract

1. Magnetic electric current generator, characterized in that it contains a frame covered with removable panels of a collapsible sealed enclosure made in the form of a rectangular parallelepiped, an inlet pipe for receiving thermal gases is installed on one end panel of the casing, and an outlet pipe on the other opposite end panel branch pipe for connection to a chimney, on one of the side removable panels of the casing an electrical connector is installed for the output of electrical energy, at least one inside is installed of a magnetic transducer of thermal energy of gases to electric energy mounted on sliding rails inside the frame, each magnetic transducer contains a pipe with a rectangular cross-section of refractory dielectric material; collector plates of non-magnetic material with electrical contacts are installed inside the pipe from two opposite sides in the direction of the exhaust gases connected to the electrical connector of the magnetic generator, on the outside of the transducer pipe perpendicular to each Permanent magnets are mounted on a pair of collector plates on permalloy or transformer iron substrates, and the total area of passage sections of the pipes of the magnetic modules at the installation site of the magnetic modules is made not less than the cross-sectional area of the inlet pipe of the magnetic generator. 2. The magnetic generator according to claim 1, characterized in that stainless steel, copper and / or aluminum are used as a non-magnetic metal of the collector plates of each magnetic module, and as a refractory dielectric material

Description

The utility model relates to the field of thermal power industry, specifically to magnetic generators of electric current.

A known conductive type electric current generator [1], based on the combustion and thermal ionization of the working substance in turbojet combustion chambers, acceleration of ionized flue gases in the Loval nozzle and separation of a chaotic mixture of electric charges of flue gases in it into separate streams of oppositely charged particles of electric current based on Hall effect.

A disadvantage of the known generator is the difficulty of its application in existing thermal power plants (TPPs) for processing residual (more than 60% [2-4]) thermal energy of the combusted fuel emitted by TPPs in the form of flue gases.

This is due to the low rate of exhaust of flue gases of TPPs, insufficient to produce electrical energy based on the Hall effect.

At the same time, it is desirable to use at least part of the thermal energy of the flue gases of TPPs for additional production of electric energy in the interest of increasing the overall efficiency of converting the chemical energy of a combustible substance into electrical energy while reducing thermal emissions into the atmosphere.

The objective of the utility model is the development of a simple-by-design magnetic electric current generator for processing the energy of thermal gases into electrical energy using the residual thermal energy of flue gases for additional generation of electric energy in thermal power plants.

The technical result that provides a solution to the problem is to simplify the production of electricity.

The essence of the utility model.

According to a utility model, a magnetic electric current generator comprises a three-dimensional frame in the form of a rectangular parallelepiped with a sealed collapsible casing. The casing contains removable side and end panels. An inlet pipe for receiving thermal gases is installed on the front end panel of the casing, and an outlet pipe for connecting to the chimney is installed on the other opposite end panel. An electric connector is installed on one of the side removable panels of the casing for outputting electricity from the magnetic generator. At least one magnetic transducer of thermal energy of gases into electrical energy is installed inside the frame of a magnetic generator on a retractable slide. Each magnetic transducer contains a pipe with a rectangular cross section of refractory dielectric material, such as ceramic and / or porcelain. Inside the pipe, on two opposite sides in the direction of the exhaust gases, current collector plates of non-magnetic material, such as copper, aluminum or stainless steel, are installed. Current collector plates are equipped with electrical contacts connected to charge-related electrical contacts of the electrical connector (contact box) of the magnetic generator. Permanent magnets are mounted on the outside of the tube of each converter perpendicularly to each pair of collector plates on permalloy or transformer iron substrates. The total area of the passage sections of the pipes of the magnetic transducers is made not less than the cross-sectional area of the inlet pipe of the magnetic generator.

This design of the magnetic generator allows for the processing of thermal gas energy into electrical energy based on the Lorentz effect [5] in the pipes of magnetic converters. For this, the spatial separation of the flow of moving flue gases through separate pipes with a total cross-sectional area not less than the cross-sectional area of the flue gas supply and exhaust pipes, and then the magnetic separation of electric charges in them, is first performed. This allows us to simultaneously solve two technical problems in the proposed design. The first task is to reduce the resistance of the magnetic generator to the flue gas flow. The second task is to increase the interception coefficient of electric charges moving in the magnetic field of the transducers, due to the increased magnetic field strength in the small tubes of the transducers due to the small distance between the magnets. The installation of magnetic transducers on retractable rails in the frame of the generator, as well as the execution of its casing with removable and detachable additionally allows to further improve maintainability of the generator, to carry out preventive cleaning of its pipes from smoke deposits.

The proposed design of the magnetic generator in comparison with the known thermal generators of electric current is simpler to manufacture and use. Due to this, the production of electricity is simplified and its cost is reduced.

In FIG. 1 is a perspective view of a magnetic electric current generator; FIG. 2 is a cross-sectional view of a magnetic generator along line AA. in FIG. 3 is a drawing illustrating the construction of a magnetic transducer.

The magnetic generator of electric current contains a three-dimensional frame 1 in the form of a rectangular parallelepiped with a sealed collapsible casing 2. The casing 2 contains removable side 3 and end 4 and 5 panels. On the front end panel 4 of the casing 2, an inlet pipe 6 for receiving thermal gases is installed, on the other opposite - end panel 5 - an outlet pipe 7 for connection with a chimney (not shown in the figures). An electrical connector (distribution terminal block) 8 is installed on the side removable panel 3 of the casing 2 for outputting electricity from the magnetic generator using the cable 9. At least one magnetic transducer 11 of gas thermal energy to electrical energy is installed on the sliding frame 10 of the magnetic generator 1. Each magnetic transducer 11 includes a pipe 12 with a rectangular cross section of refractory dielectric material, such as ceramic and / or porcelain. Inside the pipe 12, on two opposite sides in the direction of the exhaust gases, current collector plates 13 and 14 are made of non-magnetic material, for example, copper, aluminum or stainless steel. The collector plates 13 and 14 are provided with electrical contacts 15 and 16 connected to the corresponding electrical charge contacts of the electrical shield connector (junction box) 8 of the magnetic generator. Permanent magnets 17 and 18 on substrates 19 made of permalloy or transformer iron are installed on the outside of the tube 12 of each transducer perpendicularly to each pair of collector plates 13 and 14 (opposite poles). To reduce the aerodynamic drag of the magnetic generator of the electric current to the input gases, the total area of the flow sections of the pipes 12 of the magnetic transducers 11 is made not less than the cross-sectional area of the input 6 pipe of the magnetic generator.

Magnetic electric current generator operates as follows.

через кабель 9 передается потребителю электричества, например на распределительную станцию ТЭС. Отработанные и частично охлажденные (в данном случае за счет отбора первичного электричества) до оптимальной [4] температуры T=600…800°C дымовые газы передаются на тепловой энергоблок ТЭС для получения пара и вращения электрогенератора, установленного на валу паровой турбины (на фигурах не показано). Полученное вторичное электричество суммируется далее с первичным электричеством на распределительной станции ТЭС.Before starting work, the magnetic generator of electric current with nozzles 6 and 7 and corresponding gas pipes is connected to the flue of the furnace device, for example, a boiler plant of a thermal power plant. When the heating device of a thermal power station [4] is operating, an ionized flue gas stream is generated with a temperature of at least 1000 ° C, at which the density n of electric charges (electrons, positive and negative ions) in the flue gases can be n≥10 ⁸ cm ^-3 . Under the action of the traction force F _{t of the} chimney or exhaust fan-smoke exhaust of the TPP boiler, the flow of a mixture of charged particles of different types in sign enters through the pipe 6 into the front of the cavity of the sealed casing 2 at a speed V. Next, the flow of charged particles is automatically divided into many flows and penetrates through the pipes 12 magnetic transducers 11 into a transverse magnetic field H of magnets 17 and 18. Passing between the magnets 17 and 18, the negative charges (electrons and negative ions) of these gases under the influence of the Lorentz force F _l settle and held on the metal plate 13, and positive ions on the plate 14. In this case, primary electricity with a potential difference U _l = U _l (n, V _e , H, ε) is formed between the oppositely charged plates 13 and 14 of the capacitor, where n, V _e , H, ε are the density of charged particles, the speed of the flue gases, the magnetic field between the magnets 17 and 18 and the dielectric constant of the flue gases, respectively. Received electricity through contacts 15 and 16 from each converter 11 is transmitted to junction box 8. In box 8, electromechanical switching and summation of the primary electricity of converters 11 by current or voltage are performed respectively by parallel serial connection of their output contacts 15 and 16. Next, the output primary magnetic electricity generator with electric field energy

through the cable 9 is transmitted to the consumer of electricity, for example to a distribution station of thermal power plants. Waste and partially cooled (in this case, due to the selection of primary electricity) to the optimal temperature [4] T = 600 ... 800 ° C, the flue gases are transferred to the thermal power unit of the TPP to produce steam and rotate the generator installed on the shaft of the steam turbine (in the figures shown). The received secondary electricity is then added up with the primary electricity at the distribution station of the TPP.

первичного электричества, полученное на основе прямого магнитного преобразования тепловой энергии тепловых газов в магнитном генераторе электрической энергии при параллельном соединении выходных электрических контактов 15 и 16 преобразователей 11 в первом приближении определится из условияAccording to / 5 / the numerical value of electric energy

primary electricity obtained on the basis of direct magnetic conversion of thermal energy of thermal gases in a magnetic generator of electrical energy with a parallel connection of the output electrical contacts 15 and 16 of the converters 11 in a first approximation is determined from the condition

Where:

N is the number of transducers 10 in a magnetic generator;

Q is the specific amount of primary electricity generated on the plates 14 and 15 of the converter 10 per unit time (coulomb / sec);

n is the density of electric charges in thermal gases, cm ^-3 ;

ΔV is the rate of processing of thermal gases in the Converter 10, cm ³ / s;

e is the electron charge, 1.6 · 10 ^-19 pendant;

C is the capacitance of the capacitor formed by the plates 14 and 15;

ε is the relative dielectric constant of the smoke (80% - CO ₂ ) medium;

ε ₀ is the electric constant of the vacuum;

S _m - the area of the plates 14 (15);

d _m - the distance between oppositely charged plates 13 and 14 of the Converter 11.

магнитного генератора электрического тока и требуемое количество преобразователей 11 существенно зависит от размеров поперечного сечения дымоходов ТЭС и температуры дымовых газов. Так для стандартной ТЭС мощностью 100 МВт-час дополнительное электричество за счет магнитной переработки ее дымовых газов, найденное из формул (1), может составлять около 50 МВт-час. Для этого при дымоходах ТЭС диаметром от 4 до 10 метров магнитный генератора должен иметь габариты соизмеримые с габаритами дымососов ТЭС.Для указанной магнитного генератора длинна его может составлять до 9 м, площадь поперечного сечения 20×20 м, а количество магнитных преобразователей 11 - до сотен единиц.Calculations by formulas (1) show that the absolute value of the output electric energy

magnetic generator of electric current and the required number of converters 11 significantly depends on the size of the cross section of the chimneys of TPPs and the temperature of the flue gases. So for a standard thermal power plant with a capacity of 100 MWh, additional electricity due to the magnetic processing of its flue gases, found from formulas (1), can be about 50 MWh. To do this, with chimneys of TPPs with a diameter of 4 to 10 meters, the magnetic generator must have dimensions comparable with the dimensions of the TPP smoke exhausters. For the specified magnetic generator, it can be up to 9 m long, a cross-sectional area of 20 × 20 m, and the number of magnetic converters 11 up to hundreds units.

преобразователя 11 с объемом камеры единицы см³ составляет десятки кВт-час ÷ сотни кВт-часAn increase in the temperature of thermal gases above 6000 ° C, comparable to the surface temperature of the Sun, for example, when using plasma torches of the Gorynych type, dramatically reduces (to units dm ³ ) the dimensions of the magnetic generator and the number N of required converters 11 to units. This can be explained by the fact that at such a temperature as on the Sun, complete ionization of not only flue CO ₂ gases, but also the associated atmospheric air in flue gases with a particle density of n _e = 10 ¹⁹ ÷ 10 ²¹ cm ^{-3 occurs} [6-7 ]. Substituting these values in formula 1, we find that even at an efficiency = 0.0001, the output energy

Converter 11 with a chamber volume of a unit of cm ³ is tens of kWh ÷ hundreds of kWh

The proposed magnetic electric current generator allows not only to simplify the production of electricity in comparison with the well-known thermal electricity generators, but also to obtain a significant increase in the energy of existing TPPs due to in-depth fuel processing (without using additional volumes).

The utility model is developed at the level of technical proposal and preliminary calculations of the effectiveness of its use.

Sources taken into account when compiling the description: 1. RU 2013106579, IPC: F02K 9/00, 08.20.2014

2. BAZHENOV M.I. and other industrial thermal power plants. - M .: Energy, 1979, p. 184-187, p. 66.

3. Reference for the design of power supply. Under the general editorship of Yu.N. Tishchenko, N.S. Movsesova, Yu.G. Barbara. M :, Energoatomizdat. 1990. 571 p.

4. Styrikovich M.A. and other boiler units. M. - L. State Energy Publishing House. 1958. 487 p.

5. Yavorsky B.M. and Detlaf A.A. Handbook of physics for engineers and university students. M :. “Science”, 1965, 647 p.

6. Enokhovich A.S. A quick reference to physics. M :, "High School". 1969, 192 p.

7. Plasma-chemical reactions and processes, ed. L.S. Polaka, M., "Science" 1977, 320 pp.

Claims (2)

1. Magnetic electric current generator, characterized in that it contains a frame covered with removable panels of a collapsible sealed enclosure made in the form of a rectangular parallelepiped, an inlet pipe for receiving thermal gases is installed on one end panel of the casing, and an outlet pipe on the other opposite end panel branch pipe for connection to a chimney, on one of the side removable panels of the casing an electrical connector is installed for the output of electrical energy, at least one inside is installed of a magnetic transducer of thermal energy of gases to electric energy mounted on sliding rails inside the frame, each magnetic transducer contains a pipe with a rectangular cross-section of refractory dielectric material; collector plates of non-magnetic material with electrical contacts are installed inside the pipe from two opposite sides in the direction of the exhaust gases connected to the electrical connector of the magnetic generator, on the outside of the transducer pipe perpendicular to each Permanent magnets are mounted on a pair of collector plates on permalloy or transformer iron substrates, and the total cross-sectional area of the pipes of the magnetic modules at the installation site of the magnetic modules is made not less than the cross-sectional area of the inlet pipe of the magnetic generator. 2. The magnetic generator according to claim 1, characterized in that stainless steel, copper and / or aluminum are used as the non-magnetic metal of the collector plates of each magnetic module, and ceramic and / or porcelain are used as the refractory dielectric material of its pipes.

Images