RU2517182C2 - Magnetohydrodynamic power generation system - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to eclectic engineering and can be used for manufacture of magnetohydrodynamic power generation (MHD) systems based on MHD-generators generating power in tens and hundreds of kilowatts. The MHD system contains at least two MHD-generators each of them consisting of a body 1 (7) in the form of de Laval nozzle, at least one injector 2 (8) for water or water steam delivery to the input of the nozzle, a piezoelectric element for water steam generation. Electrodes 3 (9) for high-voltage arc generation are mounted in the input part of de Laval nozzle. A magnetic system 4 (10), means 5 (11) for electric current collection are placed in the area of divergent section of de Laval nozzle. MHD-generators are mounted in series so that in the process of operation working medium outgoing from the divergent section of de Laval nozzle 1 of the previous MHD-generator comes to the input of de Laval nozzle 7 of the next MHD-generator. The means 5 for electric current collection of the previous MHD-generator is connected electrically to electrodes 9 in order to generate high-voltage arc of the next MHD-generator and by a magnet of the magnetic system 10 for the next MHD-generator.

EFFECT: simplification of design, increase in power and decrease in own costs of the generated power.

4 cl, 1 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of electric power and can be used to create magnetohydrodynamic (MHD) systems for generating electricity based on MHD generators that generate electrical energy of tens or hundreds of kW.

State of the art

A MHD generator is known, comprising a housing made in the form of a hollow cylinder, the open ends of which serve to inlet and output a liquid working medium, electromagnetic windings that create a magnetic field directed perpendicular to the axis of the cylinder, and electrodes placed in the cylinder mounted parallel to the direction of the magnetic field ( see Japanese Patent No. 2713216, CL H02K 44/00, publ. 1998). In the known generator, as a working electrically conductive medium moving along the axis of the cylinder, sea water is used, for example in the form of sea waves, and an electrical load is connected to the electrodes.

Signs that are common to the known and claimed technical solutions are the presence of a housing, a magnetic system (electromagnetic windings that create a magnetic field) and means for removing electric current (electrodes placed in the cylinder mounted parallel to the direction of the magnetic field).

The reason that prevents obtaining the required technical result in a known technical solution is that the body is made in the form of a cylinder, and sea water is used as a working medium.

The closest analogue (prototype) is an MHD generator containing a hydrocarbon fuel combustion chamber designed to generate a working fluid, a housing made in the form of a diffuser connected to a combustion chamber by its inlet, an electromagnet winding located in the diffuser region, as well as electrodes installed in the diffuser along the flow of the working fluid (Polytechnical Dictionary / Editorial board: A.Yu. Ishlinsky (chap. ed.) and others - 3rd ed., revised and additional - M .: Big Russian Encyclopedia, 2000. - S.283).

Signs that are common to the known and claimed solutions are the presence of a combustion chamber, a housing made in the form of a diffuser, a magnetic system (winding of an electromagnet) and means for removing electric current (electrodes installed in the diffuser along the flow of the working fluid).

The reason that prevents obtaining the required technical result in a known technical solution is the use of hydrocarbon fuel and the design of the combustion chamber and the housing as separate devices.

SUMMARY OF THE INVENTION

The problem to which the invention is directed, is to simplify the design, increase power and reduce the cost of generated electricity.

The technical result, which mediates the solution of this problem, is to use water fuel by dissociating water into hydrogen and oxygen and burning this hydrogen in the environment of this oxygen, as well as the fact that the casing simultaneously functions as a combustion chamber due to the casing in the form of a Laval nozzle, which makes it possible to connect several MHD generators in a serial circuit with the formation of a system (battery) of MHD generators in order to increase the power of generated electricity.

The technical result is achieved in that the magnetohydrodynamic power generation system contains at least two MHD generators, each of which contains a housing made in the form of a Laval nozzle, at least one nozzle for supplying water or water vapor to the input of this nozzle, electrodes for creating a high-voltage arc installed in the inlet part of the Laval nozzle, as well as a magnetic system and means for removing electric current, located in the region of the expanding part of the Laval nozzle, while MHD generators installed sequentially, so that during the operation of the system, the working fluid emerging from the expanding part of the Laval nozzle of the previous MHD generator enters the input of the Laval nozzle of the subsequent MHD generator, and the means for removing the electric current of the previous MHD generator are electrically connected to the electrodes to create a high-voltage arc subsequent MHD generator.

The technical result is also achieved by the fact that at least one MHD generator contains at least one additional nozzle for supplying water or water vapor to the Laval nozzle in the region of its tapering part.

The technical result is also achieved by the fact that the magnetic system of the subsequent MHD generator contains an electromagnet electrically connected to a means for removing electric current from the previous MHD generator.

The technical result is also achieved by the fact that the system contains at least one piezoelectric element for the formation of water vapor.

The novelty of the claimed technical solution lies in the fact that the casing is a Laval nozzle operating on water fuel, as well as in series connection of two or more MHD generators.

List of drawings

The attached figure schematically shows a magnetohydrodynamic power generation system.

Information confirming the possibility of carrying out the invention

The system of magnetohydrodynamic generation of electricity contains at least two sequentially installed (hydrodynamically coupled) MHD generators, one of which is the previous one, the other the next.

The preceding MHD generator contains a housing 1 made in the form of a Laval nozzle, at least one nozzle 2 for supplying water or water vapor to the inlet of this nozzle, a piezoelectric element for generating water vapor (a piezoelectric element not shown), electrodes 3 for creating a high-voltage arc installed in the input part of the nozzle 1, the magnetic system 4, made in the form of a permanent magnet or in the form of a winding of an electromagnet (possibly a combination of both), located in the region of the expanding part (diffuser) of the nozzle, and means 5 for removing the electric an eye formed in the form of electrodes placed in the divergent part of the nozzle 1 along the working fluid flow. In this case, the means 5 can be performed by induction (i.e., electrodeless). In addition, the previous MHD generator contains at least one additional nozzle 6 for supplying water or water vapor to the nozzle 1 in the region of its tapering part.

The subsequent MHD generator contains a housing 7 made in the form of a Laval nozzle, at least one nozzle 8 for supplying water or water vapor to the inlet of this nozzle, a piezoelectric element for generating water vapor (the piezoelectric element is not shown), electrodes 9 for creating a high-voltage arc installed in the input part of the nozzle 7, the magnetic system 10, made in the form of a permanent magnet or in the form of an electromagnet winding (possibly a combination of both), located in the region of the expanding part (diffuser) of the nozzle, and means 11 for removing electric and made in the form of electrodes placed in the divergent part of the nozzle 7 along the working fluid flow. In this case, the means 11 can be performed by induction (i.e., electrodeless). In addition, the subsequent MHD generator contains at least one additional nozzle 12 for supplying water or water vapor to the nozzle 7 in the region of its tapering part.

MHD generators are installed sequentially so that during the operation of the system the working fluid leaving the expanding part of the Laval nozzle 1 of the previous MHD generator is fed to the input of the Laval nozzle 7 of the subsequent MHD generator, and the means 5 for removing the electric current of the previous MHD generator are electrically ( through electrical communication 13) is connected to the electrodes 9 to create a high-voltage arc of the subsequent MHD generator. In addition, if the magnetic system 10 of the subsequent MHD generator contains an electromagnet (made in the form of an electromagnet), then this electromagnet is electrically connected to the means 5 for removing the electric current of the previous MHD generator (communication is not shown).

The operation of the system is as follows.

The nozzle 2 using the nozzle 2 serves water or water vapor produced by the piezoelectric element. The electrodes 3 are connected to a high voltage current source (not shown). As a result of the passage of current in the nozzle 1 (in its inlet), water decomposes into hydrogen and oxygen and the subsequent combustion of hydrogen with the formation of a plasma in the nozzle 1, the temperature of which reaches 6000 ° C. This plasma is the working fluid of the previous MHD generator, which then passes through the tapering part of the nozzle into its diffuser (expanding part). Along the way, additional water or additional water vapor produced by the piezoelectric element enters this plasma stream through the nozzle 6. This additional water (or water vapor) decomposes under the influence of a high plasma temperature with the formation of oxygen and hydrogen, which burns up, as a result of which the total volume of plasma flowing further into the diffuser (expanding part) of nozzle 1 increases significantly. When the plasma moves through the diffuser (expanding part) of nozzle 1, this plasma enters the magnetic field formed by the magnetic system 4 of the previous MHD generator. As a result, an electric current is induced in this plasma, which is the working fluid of the MHD generator, which is diverted by means of the electric current pickup 5 to the electric circuit 13, through which high voltage is supplied to the electrodes 9 of the subsequent MHD generator. In this case, the working fluid (plasma) from the exit of the expanding part of the Laval nozzle 1 of the previous MHD generator is fed to the input of the Laval nozzle 7 of the subsequent MHD generator. At the same time, water or water vapor produced by a piezoelectric element is supplied to the Laval nozzle 7 by means of a nozzle 8. As a result of the passage of current in the nozzle 7 (in its inlet), water decomposes into hydrogen and oxygen and the subsequent combustion of hydrogen with the formation of a plasma in the nozzle 7, which mixes with the plasma coming from the exit of the nozzle 1. This total plasma is the working fluid of the subsequent MHD -generator, which then through the tapering part of the nozzle of the subsequent MHD generator enters its diffuser (expanding part). Along the way, additional water or additional water vapor produced by a piezoelectric element enters this plasma stream through the nozzle 12. This additional water (or water vapor) decomposes under the influence of a high plasma temperature with the formation of oxygen and hydrogen, which burns up, as a result of which the total volume of the plasma flowing further into the diffuser (expanding part) of the nozzle 7 increases significantly. When the plasma moves through the diffuser (expanding part) of the nozzle 7, this plasma enters the magnetic field formed by the magnetic system 10. As a result, an electric current is induced in this plasma, which is the working medium of the subsequent MHD generator, which is removed by means of an electric current pickup 11 into the output circuit (not shown).

This design of a magnetohydrodynamic (MHD) power generation system provides a significant increase in the resulting generation power. In this case, the electric current generated by the previous MHD generator of the circuit enters the subsequent MHD generator of this circuit not only to obtain a high-voltage arc in this subsequent MHD generator, but also to create a magnetic field in its expanding part (along with stationary magnets).

Claims (4)

1. The system of magnetohydrodynamic generation of electricity, which contains at least two MHD generators, each of which contains a housing made in the form of a Laval nozzle, at least one nozzle for supplying water or water vapor to the inlet of this nozzle, electrodes for creating a high-voltage arc, installed in the inlet part of the Laval nozzle, as well as a magnetic system and means for removing electric current, located in the region of the expanding part of the Laval nozzle, while the MHD generators are installed in series so that in during the operation of the system, the working fluid emerging from the expanding part of the Laval nozzle of the previous MHD generator is fed to the input of the Laval nozzle of the subsequent MHD generator, and the means for removing the electric current of the previous MHD generator are electrically connected to the electrodes to create a high-voltage arc of the subsequent MHD generator. 2. The system according to claim 1, in which at least one MHD generator contains at least one additional nozzle for supplying water or water vapor to the Laval nozzle in the region of its tapering part. 3. The system according to claim 1, in which the magnetic system of the subsequent MHD generator contains an electromagnet electrically connected to a means for removing electric current of the previous MHD generator. 4. The system according to claim 1, which contains at least one piezoelectric element for the formation of water vapor.