RU132664U1 - BALL LIGHT GENERATOR - Google Patents

Abstract

1. A ball lightning generator comprising an electric discharge chamber for activating a working substance and a device for activating a working substance, comprising a high voltage electric energy storage device with electrodes for electric arc breakdown of the working substance and a plasma stabilizer in the working chamber, the plasma stabilizer being made in the form of an electromagnetic wave generator (EMW), connected to the working chamber through an appropriate waveguide, characterized in that it further comprises collector electrodes and a reversing mechanism, the whisker of the electric discharge chamber is made of metal, the positive electrode of the high-voltage electric energy storage device is refractory, mounted movably in a heat-resistant dielectric sleeve fixed in the metal housing of the working chamber, kinematically connected to the reversing mechanism and electrically to one of the collector electrodes, the other of which is connected to the metal case a working chamber electrically connected to the negative electrode of the electric energy storage device. 2. The generator according to claim 1, characterized in that the electromagnetic wave generator is made with a wavelength equal to or a multiple of the lengths of the Fraunhofer absorption lines of radiation by the working substance in the centimeter, millimeter and / or hard ultraviolet range of the electromagnetic wave. The generator according to claim 1, characterized in that the refractory electrode is made on the basis of tungsten and / or graphite, and the heat-resistant dielectric sleeve is made of porcelain and / or ceramic.

Description

The utility model relates to the field of electrical engineering, specifically to plasma sources of electrical energy using water and / or flue (CO ₂ - 80%) gases as a working substance.

It is known [1 ÷ 2] that water and flue gases are highly concentrated sources of energy. So 1 liter of H ₂ O water contains about 1800 liters of hydrogen with a specific heat of combustion Q = 10.78 kJ / l (1.21 · 10 ⁸ J / kg). For comparison [2], the specific heat of combustion of peat is 8.1 · 10 ⁶ J / kg, domestic gas - 13.25 · 10 ⁶ J / kg, gasoline - 44 · 10 ⁶ J / kg, nuclear fuel 824 · 10 ¹¹ J / kg.

The greater the specific heat of combustion of the fuel, the lower the specific fuel consumption, the smaller the dimensions of the combustion chamber of the electric energy source and its overall dimensions with the same value of the efficiency (efficiency) of the energy source.

The breaking of the molecular bonds of hydrogen and oxygen in water, its decomposition (catalysis) into combustible components require significant energy costs. However, the use of chemical, electrolytic, electric-discharge, photo, microwave catalysts and their combinations can reduce [3 ÷ 10, 19] the costs of water dissociation to acceptable values and therefore synthesize fuel from water, which significantly exceeds the existing calorific value of hydrocarbon fuels for heat power plants (TPP). Similarly, flue gases in microwave catalysis can be decomposed into combustible components, including carbon monoxide and oxygen.

Although the specific heat (60 kJ / mol) emitted during the chemical reaction of the combustion of the constituent flue gases is significantly lower than the specific heat (532 kJ / mol) of the combustion of the constituent water, the use of flue gases to produce electrical energy is of particular interest. This is due to the increased ionization ability of CO ₂ gases (lower microwave energy costs for catalysis) and the possibility of additional production of electric energy directly at a thermal power plant due to the energy-efficient utilization of its flue gases that are harmful to the environment.

Known sources of electrical energy [11 ÷ 19], using water vapor and flue gas as a working substance and based on pulsed microwave catalysis (resonant decomposition) of a working substance into combustible components, followed by the conversion of their energy in a chemical reaction of combustion into thermal energy and then - thermal energy into electrical energy through electrodynamic [11 ÷ 15] or electromechanical [8 ÷ 10, 15 ÷ 19] conversion.

A disadvantage of known sources of electrical energy is the design complexity.

Known sources of electrical energy [8 ÷ 10], based on continuous microwave - the conversion of thermal energy of the working substance into the plasma energy of a glow discharge, hereinafter referred to as ball lightning generators.

The closest known [8 ÷ 10] in purpose and technical essence to the claimed utility model includes a ball lightning generator [9], including an electric discharge chamber for activating a working substance and a device for activating a working substance, containing a high-voltage storage of electrical energy with electrodes for electric arc breakdown of a working substance and a plasma stabilizer in the working chamber, and the plasma stabilizer is made in the form of an electromagnetic wave generator (EMW) connected to the working chamber through the corresponding s waveguide.

Moreover, the electric discharge chamber for activating the working substance is made of quartz glass with a jacket equipped with nozzles for water cooling and connection to a heat exchanger for generating heat energy for heating and hot water supply, as well as for generating steam for a steam dynamo (steam generator). The electrodes of the high-voltage electric energy storage device are rigidly fixed to the dielectric wall of the working chamber and are made in the form of tungsten metal rods with a discharge gap in the working chamber sufficient for electric arc breakdown of the working substance.

A disadvantage of the known ball lightning generator is the relatively low resource of continuous operation (fractions - units of hours), associated with the insufficient strength (fragility) of the quartz chamber and the need for frequent replacement of burned electrodes in it.

The objective of the utility model is to eliminate the shortcomings of the known ball lightning generator.

The technical result that provides the solution to this problem is to increase the reliability of the ball lightning generator.

The specified technical result and, as a result, the solution of the technical problem is provided by the fact that the ball lightning generator, including an electric discharge chamber for activating the working substance and a device for activating the working substance, containing a high-voltage storage of electrical energy with electrodes for electric arc breakdown of the working substance and a plasma stabilizer in the working chamber moreover, the plasma stabilizer is made in the form of an electromagnetic wave generator (EMW) connected to the working chamber through a corresponding According to the utility model, the waveguide additionally contains current collection electrodes and a reversing mechanism, the housing of the electric discharge chamber is made of metal, the positive electrode of the high-voltage electric energy storage device is refractory, mounted movably in a heat-resistant dielectric sleeve fixed in the metal housing of the working chamber, kinematically connected to the reversing mechanism, and electrically - with one of the collector electrodes, the other of which is connected to the metal housing of the working to amer electrically connected to the negative electrode of the electrical energy storage device.

In this case, the EME generator is made with a wavelength equal to or a multiple of the lengths of the Fraunhofer absorption lines of radiation by the working substance in the centimeter, millimeter and / or hard ultraviolet range of the EMF. The refractory electrode is made on the basis of tungsten and / or graphite, and the heat-resistant dielectric sleeve for it is made of porcelain and / or ceramics.

Additional introduction of collector electrodes and a reversing mechanism, making the case of the electric discharge chamber metallic, making the positive electrode of the high-voltage electric energy storage device refractory, installing it movably in a heat-resistant dielectric sleeve mounted in the metal case of the working chamber, the kinematic connection of the moving electrode with the reversing mechanism and the electric one with one from collector electrodes, the other of which is connected to the metal housing of the working space EASURES electrically connected to the negative electrode of the electric power storage allow push burning end of the movable electrode in the electric discharge chamber as its discharge burnup without disassembly of the camera body, and thereby increase the reliability of the device and its service life.

The implementation of the refractory electrode based on tungsten and / or graphite, and the heat-resistant dielectric sleeve for it from porcelain and / or ceramics additionally allows to increase the reliability of the device and its service life due to the increased heat resistance of these elements.

The implementation of the electromagnetic wave generator with a wavelength equal to or a multiple of the lengths of the Fraunhofer absorption lines of radiation by the working substance in the centimeter, millimeter and / or hard ultraviolet range of the electromagnetic wave can reduce the loss of electromagnetic wave for catalysis of the working substance and, as a result, reduce the power requirements of the electromagnetic wave generator.

In general, these advantages can improve the reliability and service life (uptime) of a ball lightning generator.

The figure shows an embodiment of a ball lightning generator on a steam-air working mixture of water and a liquid chemical catalyst.

The ball lightning generator contains an electric discharge chamber 1 for activating a working substance and a device for activating a working substance, including a high-voltage storage device 2 of electric energy and a stabilizer 3 of the plasma in the working chamber 1. The chamber 1 is equipped with a heat-resistant dielectric sleeve 4, reaching the central part of the chamber 1. In the dielectric sleeve 4 the electric discharge electrode 5 is movably mounted. The electrode 5 is kinematically connected to the reversing mechanism 6 and electrically connected to the collector positive electrode (output bus) 7 directly and through the electronic switch 8 - with the positive pole of the drive 2. The negative pole of the drive 2 is grounded and electrically connected to the metal housing 9 of the working chamber 1 and to the collector electrode (negative output bus) 10. The electrode 5 is made of refractory based on tungsten and / or graphite, and the heat-resistant dielectric sleeve for it is made of porcelain and / or ceramics. For electrical isolation of the reversing mechanism 6 from the conductive electrode 5, the latter is equipped with an insulator 11, rigidly connected to the outer end of the movable electrode 5. For electrical connection with the movable electrode 5, the collector bus 7 is equipped with sliding electrodes or a graphite sleeve that encloses the movable electrode 5 (not shown in the figure) . The electrode 5 and the metal case 9 of the chamber 1 form electric discharge electrodes of the storage device 2 for electric arc breakdown of the working substance in the chamber 1 and the formation of a glow discharge plasma in it, as well as for the removal of electric energy from ball lightning - unlike stabilized charges of the central and peripheral regions of the plasma. To supply the working substance and the output of the spent substance, the chamber 1 is equipped with an inlet 12 and an outlet 13 shutoff valves, then the valves 12 and 13. The valve 12 is connected through the carburetor 14 to the air medium, a capacity of 15 for water and a capacity of 16 for a liquid catalyst, for example, alkali and / or alcohol. The carburetor 14 is equipped with an air pump and organs for automatic regulation of the quality and quantity of the working mixture. The output of the valve 13 is connected to the exhaust pipe 17. The valves 12 and 13, the carburetor 14, the electronic switch 8 and the plasma stabilizer 3 are made with digital control and are connected via the signal and control inputs to the control unit 18. Block 18 includes a control panel 19 and a block 20 of digital-to-analog (DAC) and analog-to-digital converters (ADC). The control panel 19 is made in the form of a microcomputer, equipped with a display with a touch control panel, and a reprogrammable memory unit equipped with a program for initializing ball lightning of a smoldering mode, separating electric charges in the formed plasma ball and stabilizing the mode of a smoldering plasma discharge by electromagnetic radiation. The plasma stabilizer 3 is made in the form of a power-controlled electromagnetic wave generator (EMW) connected to the working chamber through the corresponding waveguide. In this case, the EME generator is made with a wavelength equal to or a multiple of the lengths of the Fraunhofer absorption lines of radiation by the working substance in the centimeter, millimeter and / or hard ultraviolet range of the EMF. To control the stabilization of the plasma in the chamber 1, the control input of the stabilizer 3 through the control unit 18 is connected to the outputs of the optical sensor 21 and the pressure sensor 22, mounted in the corresponding holes of the housing 9 of the chamber 1. The ball lightning generator operates as follows. According to a predetermined initialization program for ball lightning (ball plasma clot), the control unit 18 sets the carburetor 14 to the “working mixture enrichment” mode, opens the valve 12 and closes the valve 13 of the electric discharge chamber 1. In this case, a gas-vapor mixture of the working substance containing electrolyte is formed in the carburetor 14 "Alcohol and water" in a ratio of 40: 60%, with increased ionization ability. Next, the formed working substance enters the chamber 1 and the valve 12 closes. After filling the chamber 1 with the working substance from block 18, a signal is sent to the control input of the electronic switch 8 to initialize the working substance. In this case, from the electric energy storage device 2 or from a separate dynamo machine (not shown in the figure) through the buses 7 and 10, the potential difference sufficient for electric breakdown and electric-arc initialization of the working substance in the chamber 1 is supplied to the electrode 5 and the housing 9 of the chamber 1. by the action of an electric arc discharge in chamber 1, the working substance is ionized and, under conditions of isolation from the external air environment (reduced relaxation), a long-lived glow discharge plasma is formed. Data on the plasma parameters by brightness and pressure in the chamber 1 are taken from the corresponding sensors 21 and 22 and are used by the block 18 to stabilize the plasma by controlling the quality of the working mixture in the carburetor 14, controlling the radiation power of the emitter of the electromagnetic stabilizer 3, the temporary operating modes of the valves 12 and 13 respectively, the supply of the working mixture and the discharge of the spent substance. At the same time, in order to eliminate the breakdown of the chamber 1, the control unit 18 controls (according to the measurement speed of the pressure sensor 22) pressure surges exceeding the allowable tensile strength of the walls 9 of the chamber 1, and with the help of the valve 13 releases excess pressure in the chamber 1.

When the ball lightning generator enters the operating mode from the central (region of positive charges) and peripheral (region of negative charges) parts of chamber 1, a constant potential difference is removed from electrodes 5 and 9 and transmitted to the output buses 7 and 10.

At the same time, the control unit 18 using the electronic switch 8 connects in parallel to the output buses 7 and 10 drive 2 of electrical energy. The drive 2 stores and stabilizes the output voltage on the buses 7 and 10 of the consumer of electrical energy during the current update of the working substance as it is consumed. In the event of accidental attenuation of ball lightning in chamber 1, drive 2 is automatically used to restart the ball lightning generator.

This utility model is not limited to the above example of its implementation. In the framework of this utility model, another design of a ball lightning generator is also possible. In particular, solid-state catalysts based on rare-earth elements, for example, sponge neodymium deposited on the inner surface of air ducts and carburetor pipelines, can be used instead of liquid catalysts as a chemical catalyst for preliminary ionization of water vapor in the carburetor 14. The housing 9 of the chamber 1 can be equipped with a sealed cooling jacket and pipes for supplying a cooler and connecting to a heat exchanger to generate heat energy for heating and hot water supply, as well as for generating steam for a steam dynamo (steam generator).

The utility model is developed at the technical proposal level.

Information sources:

1. Physical encyclopedia. Ed. A.M. Prokhorova, vol. 5, Moscow: Big Russian Encyclopedia, 1998.p.81.

2. Enokhovich A.S. A quick reference to physics. M :, Higher School ", 1969, pp. 74-75.

3. The main results of scientific research of the Institute of Catalysis named after G.K.Boreskova SB RAS for 2011, Novosibirsk. Catalytic Bulletin. No. 1 (67), 2012.

4. Ostwald W. Elektrochtmie. Ihre Geschichte und Lere, Lpz., 1898.

5. V.D. Rusanov, A.I. Babaritsky, M. B. Bibikov, E. N. Gerasimov, V. K. Zhivotov, A. A. Knizhnik, B. V. Potapkin, R. V. Smirnov. Properties of a catalytically active pulsed microwave discharge of atmospheric pressure ”, DAN, 2001, vol. 377, No. 6.

6. A.I. Babaritsky, E. N. Gerasimov, S. A. Demkin, V. K. Zhivotov, A. A. Knizhnik, B. V. Potapkin, V. D. Rusanov, E. I. Ryazantsev, R.V. Smirnov, G.V.G.V. Sholin Pulse-periodic microwave discharge as a catalyst for a chemical reaction. ZhTF, 2000, vol. 70, v. 11, p. 36-41.

7. The development strategy of photocatalysts in the visible light range for the decomposition of water. Akihiko Kudo, Hideki Katol and Issei Tsuji Chemistry Letters Vol. 33 (2004), No.12 p. 1534.

8. CHUKANOV KIRIL B, QFE generators, www.chukanovenergy.com.

9. CHUKANOV KIRIL B, Methods and systems for generating high energy photons or quantum energy. US 6936971, 2003-05-22

10. CHUKANOV KIRIL B. Transition of a substance to a new state through use ofenergizer such as RF energy. US 5537009, 1996-07-16

11. GAS REACTOR, RU 2408418, 01/10/2011.

12. DEVICE FOR PRODUCING ENERGY FROM SMOKE GASES. RU 116973, 06/10/2012

13. GAS REACTOR WITH MICROWAVE EXCITATION. RU 91498, 02/10/2010

14. Device for the disposal of flue gases. WO 2010123391, 04.20.2009.

15. PLASMA SOURCE OF ENERGY, RU 2011127270, 01/10/2013.

16. Internal combustion engine. WO 2011005135, F02P 23/00, F02M 27/00, F02B 51/00, H05H 1/46, 10.28.2010.

17. Hybrid car. RU 2011119709, B60W 20/00, 11/27/2012

18. Small-sized unmanned aerial vehicle for monitoring territories of fires, terrorist acts and technological disasters. RU 105884, B64C 39/02, 06/27/2011.

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Claims (3)

1. A ball lightning generator comprising an electric discharge chamber for activating a working substance and a device for activating a working substance, comprising a high voltage electric energy storage device with electrodes for electric arc breakdown of the working substance and a plasma stabilizer in the working chamber, the plasma stabilizer being made in the form of an electromagnetic wave generator (EMW), connected to the working chamber through an appropriate waveguide, characterized in that it further comprises collector electrodes and a reversing mechanism, the whisker of the electric discharge chamber is made of metal, the positive electrode of the high-voltage electric energy storage device is refractory, mounted movably in a heat-resistant dielectric sleeve fixed in the metal housing of the working chamber, kinematically connected to the reversing mechanism and electrically to one of the collector electrodes, the other of which is connected to the metal case a working chamber electrically connected to the negative electrode of the electric energy storage device. 2. The generator according to claim 1, characterized in that the electromagnetic wave generator is made with a wavelength equal to or a multiple of the lengths of the Fraunhofer absorption lines of radiation by the working substance in the centimeter, millimeter and / or hard ultraviolet range of the electromagnetic wave. 3. The generator according to claim 1, characterized in that the refractory electrode is made on the basis of tungsten and / or graphite, and the heat-resistant dielectric sleeve is made of porcelain and / or ceramic.

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